1CM73_1E(2)

Operation Guide for HSUPA Test Setup according to 3GPP TS 34.121 Application Note

Products: | R&SCMU200

Most of the tests specified in standard TS 34.121 [1] for 3GPP Rel-6 can be performed with R&S®CMU200. This document provides a step by step guide on how to perform Rel-6 measurements on transmitter characteristics and performance tests according to TS 34.121 V8.7.0 clauses 5 and 10 with stand-alone R&S®CMU200. Test cases that require additional instruments, e.g. fading generator (R&S®SMU200A or R&S®AMU200A) will be discussed in brief in this application note with recommended reference. A set of *.sav files based on R&S®CMU200 firmware V5.03for UE supporting operating band I and power class 3 in RMC 12.2 kbps + HSPA is attached to this application note. Note: This application note substitutes for application note RCS0712-0053.

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Table of Contents

1CM73_1E Rohde & Schwarz Operation Guide for HSUPA Test Setup according to 3GPP TS34.121 3

Table of Contents 1 Introduction......................................................................................... 5

1.1 Covered Tests in Accordance with TS 34.121 ..........................................................5 1.2 Information on Using *.SAV Files in R&S®CMU200..................................................6

2 Rel-6 Transmitter Characteristics ..................................................... 7 2.1 Generic Call Setup for Transmitter Characteristics .................................................7 2.2 Maximum Output Power with HS-DPCCH and E-DCH (5.2B) ................................25 2.3 UE Relative Code Domain Power Accuracy for HS-DPCCH and E-DCH (5.2D)...31 2.4 Spectrum Emission Mask with E-DCH (5.9B) .........................................................39 2.5 Adjacent Channel Leakage Power Ratio (ACLR) with E-DCH (5.10B)..................42 2.6 Relative Code Domain Error with HS-DPCCH and E-DCH (5.13.2B).....................45

3 Rel-6 Performance Requirements ................................................... 51 3.1 Generic Call Setup for Performance Requirements...............................................51 3.2 Detection of E-DCH HARQ ACK Indicator Channel (E-HICH): Single Link

Performance (10 ms TTI) (10.2.1.1) ..........................................................................56 3.3 Detection of E-DCH HARQ ACK Indicator Channel (E-HICH): Single Link

Performance (10 ms TTI, Type 1) (10.2.1.1A) ..........................................................60 3.4 Detection of E-DCH HARQ ACK Indicator Channel (E-HICH): Single Link

Performance (2 ms TTI) (10.2.1.2) ............................................................................63 3.5 Detection of E-DCH HARQ ACK Indicator Channel (E-HICH): Single Link

Performance (2 ms TTI, Type 1) (10.2.1.2A) ............................................................67 3.6 Detection of E-DCH Relative Grant Channel (E-RGCH): Single Link Performance

(10 ms TTI) (10.3.1.1) .................................................................................................70 3.7 Detection of E-DCH Relative Grant Channel (E-RGCH): Single Link Performance

(10 ms TTI, Type 1) (10.3.1.1A) .................................................................................77 3.8 Detection of E-DCH Relative Grant Channel (E-RGCH): Single Link Performance

(2 ms TTI) (10.3.1.2)....................................................................................................81 3.9 Detection of E-DCH Relative Grant Channel (E-RGCH): Single Link Performance

(2 ms TTI, Type 1) (10.3.1.2A) ...................................................................................86 3.10 Demodulation of E-DCH Absolute Grant Channel (E-AGCH): Single Link

Performance (10.4.1) .................................................................................................90 3.11 Demodulation of E-DCH Absolute Grant Channel (E-AGCH): Single Link

Performance (Type 1) (10.4.1A) ................................................................................94

4 Summary of R&S®CMU200 *.SAV Files........................................... 97

Table of Contents


5 Reference .......................................................................................... 98

6 Ordering Information........................................................................ 99

Introduction

Covered Tests in Accordance with TS 34.121


1 Introduction Most of the tests specified in standard TS 34.121 [1] for 3GPP Rel-6 can be performed with R&S®CMU200. This document provides a step by step guide on how to perform Rel-6 measurements on transmitter characteristics and performance tests according to TS 34.121 V8.7.0 clauses 5 and 10 with stand-alone R&S®CMU200 for UE supporting operating band I and power class 3. Test cases that require additional instruments, e.g. fading generator (R&S®SMU200A or R&S®AMU200A) will be discussed in brief in this application note with recommended reference. A set of *.sav files based on R&S®CMU200 firmware V5.03 for UE supporting operating band I and power class 3 in RMC 12.2 kbps + HSPA is attached to this application note. Information on these *.sav files within this application note is marked with the symbol

Note: This application note substitutes for application note RCS0712-0053.

1.1 Covered Tests in Accordance with TS 34.121 Table 1 shows the Rel-6 transmitter characteristics and performance tests that can be performed with R&S®CMU200.

Introduction

Information on Using *.SAV Files in R&S®CMU200


Transmitter characteristics and performance tests of 3GPP Rel-6 supported by R&S®CMU200 Test Clause Test Parameter

5.2B Maximum output power with HS-DPCCH and E-DCH

5.2D UE relative code domain power accuracy for HS-DPCCH and E-DCH

5.9B Spectrum emission mask with E-DCH

5.10B Adjacent channel leakage power ratio (ACLR) with E-DCH

Transmitter characteristics

5.13.2B Relative code domain error with HS-DPCCH and E-DCH

10.2.1.1 Detection of E-DCH HARQ ACK Indicator Channel (E-HICH): Single Link Performance (10 ms TTI)*

10.2.1.1A Detection of E-DCH HARQ ACK Indicator Channel (E-HICH): Single Link Performance (10 ms TTI and Type 1)*

10.2.1.2 Detection of E-DCH HARQ ACK Indicator Channel (E-HICH): Single Link Performance (2 ms TTI)*

10.2.1.2A Detection of E-DCH HARQ ACK Indicator Channel (E-HICH): Single Link Performance (2 ms TTI and Type 1)*

10.3.1.1 Detection of E-DCH Relative Grant Channel (E-RGCH): Single Link Performance (10 ms TTI)*

10.3.1.1A Detection of E-DCH Relative Grant Channel (E-RGCH): Single Link Performance (10 ms TTI and Type 1)*

10.3.1.2 Detection of E-DCH Relative Grant Channel (E-RGCH): Single Link Performance (2 ms TTI)*

10.3.1.2A Detection of E-DCH Relative Grant Channel (E-RGCH): Single Link Performance (2 ms TTI and Type 1)*

10.4.1 Demodulation of E-DCH Absolute Grant Channel (E-AGCH): Single Link Performance*

Performance requirements

10.4.1A Demodulation of E-DCH Absolute Grant Channel (E-AGCH): Single Link Performance (Type 1)*

* Requires additional instruments besides R&S®CMU200 Table 1: 3GPP Rel-6 measurement supported by R&S®CMU200

1.2 Information on Using *.SAV Files in R&S®CMU200

In order to recall *.sav file successfully without warning and error

• Activate WCDMA FDD-UE Signalling function group before recalling *.sav file

• Use the same WCDMA firmware version as indicated on the folder for Rel-6 *.sav files, e.g. recall *.sav files in folder R6_V5.03 with activated WCDMA firmware of V5.03

Rel-6 Transmitter Characteristics

Generic Call Setup for Transmitter Characteristics


2 Rel-6 Transmitter Characteristics

2.1 Generic Call Setup for Transmitter Characteristics All parameters of transmitter characteristics are defined using the UL reference measurement channel (RMC) 12.2 kbps and Fixed Reference Channels (FRC H-Set 1, QPSK) as specified in TS 34.121 Annex C.11.1 and C.8.1.1 unless stated otherwise. Loopback test mode 1 as specified in 5.3.2.3 and 5.3.2.6 of TS 34.109 [2] is used for looping back both the 12.2 kbps RMC and HSDPA to E-DCH. E-DCH call is setup according to 7.3.9 of TS 34.108 [3]. Table 2 shows the UL RLC SDU size for E-DCH transmitter characteristics supported by R&S®CMU200.

UL RLC SDU size for E-DCH tests supported by R&S®CMU200

TC Clause TS 34.121-1 E-DCH Test Cases Inter-TTI DL SDU size

[bits] Number of DL SDUs per DL transmission

UL RLC SDU Size [bits]

5.2B Maximum Output Power with HS-DPCCH and E-DCH 3 (H-Set 1) 2936 1 2936 bits

(1*DL RLC SDU)

5.2D UE Relative Code Domain Power Accuracy for HS-DPCCH and E-DCH 3 (H-Set 1) 2936 1 2936 bits

(1*DL RLC SDU)

5.9B Spectrum Emission Mask with E-DCH 3 (H-Set 1) 2936 1 2936 bits

(1*DL RLC SDU)

5.10B ACLR with E-DCH 3 (H-Set 1) 2936 1 2936 bits (1*DL RLC SDU)

5.13.2B Relative Code Domain Error with HS-DPCCH and E-DCH 3 (H-Set 1) 2936 1 2936 bits

(1*DL RLC SDU)

10.2.1.1 Detection of E-HICH -Single Link Performance (10ms) 3 (H-Set 1) 2936 1 2936 bits

(1*DL RLC SDU)

10.2.1.2 Detection of E-HICH -Single Link Performance (2ms) 3 (H-Set 1) 2936 1 5872 bits

(2*DL RLC SDU)

10.3.1.1 Detection of E-RGCH - Single Link Performance (10ms) 3 (H-Set 1) 2936 1 2936 bits

(1*DL RLC SDU)

10.3.1.2 Detection of E-RGCH - Single Link Performance (2ms) 3 (H-Set 1) 2936 1 5872 bits

(2*DL RLC SDU)

10.4.1 Demodulation of E-AGCH ( Single Link Performance) 3 (H-Set 1) 2936 1 8808 bits

(3*DL RLC SDU) Table 2: UL RLC SDU size for E-DCH tests supported by R&S®CMU200 (Subset of Table C.11.3.1 of TS 34.121 [1]) Configuration in R&S®CMU200: Network � Packet Switched Domain � On BS Signal � Circuit Switched � DCH (Dedicated Chn.) Type � RMC BS Signal � Circuit Switched � RMC Settings � Reference Channel Type � 12.2 kbps + HSPA 34.108 BS Signal � Circuit Switched � RMC Settings � Test Mode � Loop Mode 1 * BS Signal � Circuit Switched � RMC Settings � HSPA � HSUPA UL RLC SDU Size � 2936 Bit BS Signal � Circuit Switched � RMC Settings � HSPA � HSPA Test Loop � Loop Mode 1




BS Signal � Packet Switched � DCH (Dedicated Chn.) Type � HSUPA Test Mode BS Signal � Packet Switched � HSUPA Test Mode � Radiobearer Setup � RMC 12.2 kbps + HSPA BS Signal � Packet Switched � HSUPA Test Mode � HSUPA UL RLC SDU Size �2936 Bit ** * Loop Mode 1 is automatically selected when Reference Channel Type is set to 12.2 kbps + HSPA 34.108 ** HSUPA UL RLC SDU Size in Circuit Switched and Packet Switched is set to the same value automatically

Figure 1(a): RMC 12.2 kbps + HSPA 34.108 configuration




Figure 1(b): RMC 12.2 kbps + HSPA 34.108 configuration

RADIO BEARER SETUP message in 9.2.1 of TS 34.108 [3] as shown in Table 3(a) is used to configure E-DCH call with the following exceptions in Table 4(a), 4(b), 4(c) and 4(d). For RRC CONNECTION SETUP, “Contents of RRC CONNECTION SETUP message: UM” message in 9.2 of TS 34.108 [3] is used to configure E-DCH RF test cases with the following exceptions as shown in Table 3(b).




Notes: Condition A1: not using E-DCH 4 codes Condition A2: using E-DCH 4 codes Table 3(a): Contents of RADIO BEARER SETUP message: AM or UM (E-DCH and HSDPA) (Subset of 9.2.1 of TS 34.108 [3])

Contents of RADIO BEARER SETUP message: AM or UM (E-DCH and HSDPA) Information Element Condition Value/remark Version

Added or Reconfigured TrCH information list A1 1 TrCH added

- E-DCH Transmission Time 10 ms

- HARQ RV Configuration Rv0

- Added or reconfigured E-DCH MAC-d flow

- E-DCH MAC-d flow power offset 0

- E-DCH MAC-d flow maximum number of retransmissions 7

Added or Reconfigured UL TrCH information list A1 1 TrCH added

- E-DCH Transmission Time Interval 2 ms

- HARQ RV Configuration Rv0

- Added or reconfigured E-DCH MAC-d flow (for DCCH)

- E-DCH MAC-d flow power offset 0

- E-DCH MAC-d flow maximum number of retransmissions 7

E-DCH info A1, A2 Rel-6

- MAC-es/e reset indicator TRUE

- E-DPCCH info

- E-DPCCH/DPCCH power offset 0

- Happy bit delay condition 100 ms

- E-TFCI boost info Not present Rel-7

- E-TFCI BetaED SwitchE-DPDCH power interpolation Not present Rel-7

- E-DPDCH info A1

- E-TFCI table index 0

- E-DCH minimum set E-TFCI 9

- Maximum channelisation codes 2sf4

- PLnon-max 0.84

- Power Offset for Scheduling Info 0

- E-DPDCH info A2



- Maximum channelisation codes 2sf2 and 2sf4

- PLnon-max 0.84

- Power Offset for Scheduling Info 0

- Scheduled Transmission configuration A1, A2

- 2 ms scheduled transmission grant HARQ process Not present

- Serving Grant Not present




Table 3(b): Contents of RRC CONNECTION SETUP message: UM (section 7.3.9.4.3 of TS 34.108 [3])

Table 4(a): Contents of RADIO BEARER SETUP message: AM or UM (Test Loop Mode 1) (Table5.2B.1A of TS 34.121 [1])

Table 4(b): Contents of RADIO BEARER SETUP message: AM or UM (E-DCH and HSDPA) for Sub-tests 1, 2, 4, 5 (Table5.2B.2, Table 5.2D.3 and Table 5.13.2B.4 of TS 34.121 [1])

Contents of RRC CONNECTION SETUP message: UM Information Element Value/remark

- Default DPCH Offset Value Arbitrary set to value 1536…306176 by step of

2560 (this corresponds to a 0.5 slot timing offset between the DPCCH and the HS-DPCCH)

Contents of RADIO BEARER SETUP message: AM or UM (E-DCH and HSDPA) Information Element Value/Remark

UL Transport channel information for all transport channels

- 2 bit CTFC 3

- Power offset Information

- CHOICE Gain Factors Signalled Gain Factors

- CHOICE mode FDD

- Gain factor ßc Value used in test: see Table 5

- Gain factor ßd Value used in test: see Table 5

CHOICE channel requirement Uplink DPCH info

- Power Control Algorithm Algorithm2

Note: All other 2 bit CTFC values use computed gain factors as in the default message

Contents of RADIO BEARER SETUP message: AM or UM (E-DCH and HSDPA) for Sub-tests 1, 2, 4, 5

Information Element Value/Remark

E-DCH info Uplink DPCH info

- E-DPDCH info

- Reference E-TFCIs 5 E-TFCIs

- Reference E-TFCI 11

- Reference E-TFCI PO 4












Table 4(c): Contents of RADIO BEARER SETUP message: AM or UM (E-DCH and HSDPA) for Sub-tests 3 (Table5.2B.3, Table 5.2D.4 and Table 5.13.2B.5 of TS 34.121 [1])

Table 4(d): Contents of RADIO BEARER SETUP message: AM or UM (E-DCH and HSDPA) Table5.2B.4, Table 5.2D.5 and Table 5.13.2B.6 of TS 34.121 [1]) Configuration in R&S®CMU200: BS Signal � HSDPA HS-DSCH � CQI Feedback Cycle � 4 ms BS Signal � HSDPA HS-DSCH � CQI Repetition Factor � 2BS Signal � HSDPA HS-DSCH � ACK/NACK Repetition Factor � 3BS Signal � HSDPA HS-DSCH � Channel Configuration Type � Fixed Reference Channel BS Signal � HSDPA HS-DSCH � Fixed Reference Channel � H-Set Selection � H-Set 1 QPSK BS Signal � HSUPA � TTI Mode � 10 ms (E-DCH category 1 to 5) or 2 ms (E-DCH category 6) BS Signal � Downlink Physical Channels � DL DPCH Timing Offset � 6 * 256 chip UE Signal � HSUPA � E-TFCI Table Index � 0UE Signal � HSUPA � Minimum Set E-TFCI � 9UE Signal � HSUPA � Happy Bit Delay Condition � 100 ms UE Signal � HSUPA � Puncturing Limit PLnon-max � 0.84 UE Signal � HSUPA � Maximum Channelisation Code � 2xSF4 (for E-DCH category 1 to 5) or 2xSF2 and 2xSF4 (for E-DCH category 6) UE Signal � HSUPA � Initial Serving Grant � Value � Off UE Signal � HSUPA � RAB H-ARQ Profile � H-ARQ Power Offset � 0 dB UE Signal � HSUPA � RAB H-ARQ Profile � Maximum Number of Retransmissions � 7

Contents of RADIO BEARER SETUP message: AM or UM (E-DCH and HSDPA) for Sub-test 3

Information Element Value/Remark

E-DCH info Uplink DPCH info

- E-DPDCH info

- Reference E-TFCIs 2 E-TFCIs






CHOICE channel requirement Uplink DPCH info

- Power Control Algorithm Algorithm2 - ∆ACK Value used in test: see Table 5 - ∆NACK Value used in test: see Table 5

- Ack-Nack repetition factor 3 (required for continuous HS-DPCCH signal)

E-DCH info

- E-DPCCH/DPCCH power offset Value used in test: see Table 5

Downlink HS-PDSCH Information

- Measurement Feedback Info

- CQI Feedback cycle, k 4 ms

- CQI repetition factor 2 (required for continuous HS-DPCCH signal) - ∆CQI Value used in test: see Table 5




UE Signal � HSUPA � HSUPA Gain Factors � Number of Reference E-TFCIs � 5(sub-tests 1, 2, 4, 5) or 2 (sub-test 3) UE Signal � HSUPA � Reference E-TFCI 1…4 � 11 67 71 75 (for sub-tests 1, 2, 4, 5) or 11 92 (for sub-test 3) UE Signal � HSUPA � Reference E-TFCI 5…8 � 81(for sub-tests 1, 2, 4, 5) UE Signal � HSUPA � Reference E-TFCI Power Offset � 4 18 23 26 27 (for sub-tests 1, 2, 4, 5) or 4 18 (for sub-test 3) BS Signal � TPC Settings � TPC Algorithm � Algorithm 2

Figure 2(a): RADIO BEARER SETUP message configuration




Figure 2(b): RADIO BEARER SETUP message configuration

Figure 2(c): RADIO BEARER SETUP message configuration




Figure 2(d): RADIO BEARER SETUP message configuration

Figure 2(e): DPCH timing offset configuration




Table 5, 6(a), 6(b) and 7 show the β values for transmitter characteristics with HS-DPCCH and E-DCH, signalled value for gain factors βc, βd, ∆ACK, ∆NACK, ∆CQI and ∆E-DPCCH in R&S®CMU200 and summary of gain factor setting in R&S®CMU200 respectively.

β values for transmitter characteristics tests with HS-DPCCH and E-DCH

Sub-test βc βd

βd(SF) βc/βd

βHS (Note 1)

βec βed (Note 5, Note 6)

βed(SF)

βed(Codes)

CM (dB)

(Note 2)

MPR (dB)

(Note 2)

AG Index (Note 6)

E-TFCI

1 11/15 (Note 3)

15/15 (Note 3)

64 11/15 (Note 3)

22/15 209/ 225

1309/225 4 1 1.0 0.0 20 75

2 6/15 15/15 64 6/15 12/15 12/15 94/75 4 1 3.0 2.0 12 67

3 15/15 9/15 64 15/9 30/15 30/15

βed1: 47/15 βed2: 47/15

44 2 2.0 1.0 15 92

4 2/15 15/15 64 2/15 4/15 2/15 56/75 4 1 3.0 2.0 17 71

5 15/15 (Note 4)

15/15 (Note 4) 64 15/15

(Note 4) 30/15 24/15 134/ 15 4 1 1.0 0.0 21 81

Notes: 1. ∆ACK, ∆NACK and ∆CQI = 30/15 with βHS = 30/15 * βC.2. CM = 1 for βc/βd =12/15, βHS/βC =24/15. For all other combinations of DPDCH, DPCCH, HS- DPCCH, E-DPDCH and E-DPCCH the MPR is based on the relative CM difference. 3. For subtest 1 the βC/βd ratio of 11/15 for the TFC during the measurement period (TF1, TF0) is achieved by setting the signalled gain factors for the reference TFC (TF1, TF1) to βc = 10/15 and βd = 15/15. 4. For subtest 5 the βC/βd ratio of 15/15 for the TFC during the measurement period (TF1, TF0) is achieved by setting the signalled gain factors for the reference TFC (TF1, TF1) to βc = 14/15 and βd = 15/15. 5. In case of testing by UE using E-DPDCH Physical Layer category 1, Sub-test 3 is omitted according to TS25.306 Table 5.1g. 6. βed cannot be set directly, it is set by Absolute Grant Value. Table 5: β values for transmitter characteristics tests with HS-DPCCH and E-DCH (Table C.11.1.3 of TS 34.121 [1])

Table 6(a): Signalled value for gain factors βc and βd in R&S®CMU200

Signalled value for gain factors βc and βdSignalled value for βc and βd Quantized amplitude ratio for βc and βd

15 15/15

14 14/15

13 13/15

12 12/15

11 11/15

10 10/15

9 9/15

8 8/15

7 7/15

6 6/15

5 5/15

4 4/15

3 3/15

2 2/15

1 1/15




Table 6(b): Signalled value for gain factors ∆ACK, ∆NACK, ∆CQI and ∆E-DPCCH in R&S®CMU200

Summary of gain factor setting in R&S®CMU200

Sub-test βc βd ∆ACK ∆NACK ∆CQI ∆E-DPCCH AG Index E-TFCI

1 10 15 8 8 8 6 20 75

2 6 15 8 8 8 8 12 67

3 15 9 8 8 8 8 15 92

4 2 15 8 8 8 5 17 71

5 14 15 8 8 8 7 21 81 Table 7: Summary of gain factor setting in R&S®CMU200

Configuration in R&S®CMU200: UE Signal � UE Gain Factors � Packet Data � HSDPA / HSUPA � βc � 10 (sub-test 1), 6 (sub-test 2), 15 (sub-test 3), 2 (sub-test 4) or 14 (sub-test 5) UE Signal � UE Gain Factors � Packet Data � HSDPA / HSUPA � βd � 15 (sub-test 1), 15 (sub-test 2), 9 (sub-test 3), 15 (sub-test 4) or 15 (sub-test 5) UE Signal � UE Gain Factors � Packet Data � HSDPA / HSUPA � ∆ACK � 8UE Signal � UE Gain Factors � Packet Data � HSDPA / HSUPA � ∆NACK � 8UE Signal � UE Gain Factors � Packet Data � HSDPA / HSUPA � ∆CQI � 8UE Signal � HSUPA � HSUPA Gain Factors � ∆E-DPCCH � 6 (sub-test 1), 8 (sub-test 2), 8 (sub-test 3), 5 (sub-test 4) or 7 (sub-test 5) BS Signal � HSUPA � E-AGCH � AG Pattern � AG Index � 20 (sub-test 1), 12 (sub-test 2), 15 (sub-test 3), 17 (sub-test 4) or 21 (sub-test 5)

Signalled value for gain factors ∆ACK, ∆NACK, ∆CQI and ∆E-DPCCH Signalled value for ∆ACK, ∆NACK and ∆CQI Quantized amplitude ratio (βHS / βc)

8 30/15

7 24/15

6 19/ 5

5 15/15

4 12/15

3 9/15

2 8/15

1 6/15

0 5/15




Figure 3(a): β values for transmitter characteristics tests with HS-DPCCH and E-DCH configuration

Figure 3(b): β values for transmitter characteristics tests with HS-DPCCH and E-DCH configuration




Table 8 shows the settings for serving cell during measurement with HS-DPCCH and E-DCH.

Table 8: Settings for the serving cell during measurement with HS-DPCCH and E-DCH (Table 5.2B.4A, Table 5.2D.6, Table 5.9B.2, Table 5.10B.1A and Table 5.13.2B.7 of TS 34.121 [1]) Configuration in R&S®CMU200: Network � Cell Reselection Information � Qqualmin � - 24 dB Network � Cell Reselection Information � Qrxlevmin � - 58 dBm * 2 + 1 UE Signal � UE Power Control � Open Loop � Max Allowed UE Power � 21.0 dBm BS Signal � Node-B Settings � Output Channel Power (Ior) � -86 dBm

Figure 4(a) : Setting for the serving cell

Settings for the serving cell during measurement with HS-DPCCH and E-DCHParameter Unit Cell 1

Cell type Serving cell

UTRA RF Channel Number Test dependent value

Qqualmin dB -24

Qrxlevmin dBm -115

UE_TXPWR_MAX_RACH dBm +21

Ior dBm/3.84 MHz -86




Figure 4(b) : Setting for the serving cell Table 9 shows the downlink physical channel parameters for HSUPA measurement for subclauses 5.2B, 5.2D, 5.9B, 5.10B and 5.13.2B as specified in Table E.5A.1 of TS 34.121 [1].

Notes: 1. During TTIs, in which the HS-PDSCH is not allocated to the UE via HS-SCCH signalling, the HS-PDSCH

shall be transmitted continuously with constant power 2. During TTIs, in which the HS-SCCH is not allocated to the UE the HS-SCCH shall be transmitted

continuously with constant power. Table 9: Downlink physical channels for E-DCH transmitter characteristics tests (Table E.5A.1 of TS 34.121 [1])

Downlink physical channel parameters for E-DCH transmitter characteristics tests Parameter during measurement Unit Value

P-CPICH_Ec/Ior dB -10

P-CCPCH and SCH_Ec/Ior dB -12

PICH_Ec/Ior dB -15

HS-PDSCH dB -3 (Note 1)

HS-SCCH_1 dB -8 (Note 2)

DPCH_Ec/Ior dB -10

E-AGCH dB -20

E-HICH dB -20

E-RGCH dB DTX’d

OCNS_Ec/Ior dB Necessary power so that total transmit power spectral density of Node B (Ior) adds to one




Configuration in R&S®CMU200: BS Signal � Node-B Settings � Level Reference � Output Channel Power (Ior) BS Signal � Downlink Physical Channels � P-CPICH � -10.0 dB BS Signal � Downlink Physical Channels � P-SCH � -15.0 dB BS Signal � Downlink Physical Channels � S-SCH � -15.0 dB BS Signal � Downlink Physical Channels � P-CCPCH � -12.0 dB BS Signal � Downlink Physical Channels � PICH � -15.0 dB BS Signal � Downlink Physical Channels � DPDCH Level Config � -10.0 dB BS Signal � Downlink Physical Channels � HSDPA Channels � On BS Signal � Downlink Physical Channels � HS-SCCH � HS-SCCH#1 � Level �-8.0 dB BS Signal � Downlink Physical Channels � HS-SCCH � HS-SCCH#2 � Level � Off BS Signal � Downlink Physical Channels � HS-SCCH � HS-SCCH#3 � Level � Off BS Signal � Downlink Physical Channels � HS-SCCH � HS-SCCH#4 � Level � Off BS Signal � Downlink Physical Channels � HS-SCCH � HS-SCCH Selection � 1BS Signal � Downlink Physical Channels � HS-SCCH � Number of HS-SCCH � 4BS Signal � Downlink Physical Channels � HS-SCCH � Unscheduled Subframes �Transmit Dummy UEID BS Signal � Downlink Physical Channels � HS-PDSCH � Level (All Active Codes) � -3.0 dB BS Signal � Downlink Physical Channels � HSUPA Channels � On BS Signal � Downlink Physical Channels � E-AGCH � E-AGCH � -20.0 dB BS Signal � Downlink Physical Channels � E-RGCH/E-HICH � E-RGCH/E-HICH �-20.0 dB BS Signal � Downlink Physical Channels � E-RGCH Active � Off

Figure 5(a) : Downlink physical channels configuration according to Table 9




Figure 5(b): Downlink physical channels configuration according to Table 9

Figure 5(c): Downlink physical channels configuration according to Table 9




Figure 5(d): Downlink physical channels configuration according to Table 9

Figure 5(e): Downlink physical channels configuration according to Table 9




A HSUPA call is setup according to TS 34.108 [3] subclause 7.3.9. To establish a HSUPA connection, press ‘Connect UE (CS)’ (E-DCH category 1 to 5) or ‘Connect UE (PS)’ (E-DCH category 6) on R&S®CMU200 once UE has registered/attached with R&S®CMU200.

Note: With 12.2 kbps + HSPA 34.108 reference measurement channel, packet switched connection is setup automatically after the circuit switched connection so that the R&S®CMU200 reaches the signaling state PS: Established, CS: Connected.

E-DCH category 1 to 5

For sub-test 1, recall HSUPATx1.sav and establish CS call. For sub-test 2, recall HSUPATx2.sav and establish CS call.

For sub-test 3, recall HSUPATx3.sav and establish CS call. For sub-test 4, recall HSUPATx4.sav and establish CS call. For sub-test 5, recall HSUPATx5.sav and establish CS call. E-DCH category 6

For sub-test 1, recall HSUPATx1.sav, modify the following configuration and establish PS call. UE Signal � HSUPA � Maximum Channelisation Code � 2xSF2 and 2xSF4 For sub-test 2, recall HSUPATx2.sav, modify the following configuration and establish PS call. UE Signal � HSUPA � Maximum Channelisation Code � 2xSF2 and 2xSF4 For sub-test 3, recall HSUPATx3.sav, modify the following configuration and establish PS call. UE Signal � HSUPA � Maximum Channelisation Code � 2xSF2 and 2xSF4 For sub-test 4, recall HSUPATx4.sav, modify the following configuration and establish PS call. UE Signal � HSUPA � Maximum Channelisation Code � 2xSF2 and 2xSF4 For sub-test 5, recall HSUPATx5.sav, modify the following configuration and establish PS call. UE Signal � HSUPA � Maximum Channelisation Code � 2xSF2 and 2xSF4


Maximum Output Power with HS-DPCCH and E-DCH (5.2B)


2.2 Maximum Output Power with HS-DPCCH and E-DCH (5.2B)

The maximum output power with HS-DPCCH and E-DCH measures the maximum power the UE can transmit when HS-DPCCH and E-DCH is fully or partially transmitted during a DPCCH timeslot. The measurement period shall be at least one timeslot. An excess maximum output power may interfere other channels or other systems. A small maximum output power decreases the coverage area. Table 10 shows the test requirements for maximum output power with HS-DPCCH and E-DCH. This test applies to all FDD UE of Release 6 and later releases that support HSDPA and E-DCH.

Notes: 1. The test procedure will result in a power slightly below the maximum, and therefore the lower limits in

Table 10 are made lower by 1.5 dB. 2. The test procedure allows UE to decrease its maximum transmit power for E-TFC selection in sub-test 1

and 5, and therefore the lower limits of sub-test 1 and 5 in Table 10 are made lower by 1.5 dB. Table 10: Maximum output power with HS-DPCCH and E-DCH (Table5.2B.5 of TS 34.121 [1]) Fixed Reference Channels (FRC H-Set 1, QPSK version), RADIO BEARER SETUP message, sub-test 1, downlink physical channels, and serving cell are configured in R&S®CMU200 as specified in section 2.1. The test requires power control bits to be set such that the UE power to be at least 7.5 dB lower than the maximum output power, to give one TPC_cmd = +1 command and to give one TPC_cmd = -1 command to the UE. Configuration in R&S®CMU200: BS Signal � TPC Settings � TPC Algorithm � Algorithm 2 BS Signal � TPC Settings � TPC Pattern Setup � Set 1 BS Signal � TPC Settings � Set 1 � Pattern Type � Closed Loop BS Signal � TPC Settings � Set 1 � UL Target Power � 15.0 dBm BS Signal � TPC Settings � Set 2 � Pattern Type � Single Pattern + Alternating BS Signal � TPC Settings � Set 2 � Pattern � 11111 (for TPC_cmd = +1 command) BS Signal � TPC Settings � Set 3 � Pattern Type � Single Pattern + Alternating BS Signal � TPC Settings � Set 3 � Pattern � 00000 (for TPC_cmd = -1 command) Menu � Power � Application � Maximum Power Maximum Power � Maximum Power � Control � Maximum Power � TPC � Manual

Maximum output power with HS-DPCCH and E-DCH Power Class 3 Power Class 4

Sub-test in Table 5 Power (dBm) Tol (dB) Power (dBm) Tol (dB)

1 +24 +1.7/-6.7 +21 +2.7/-5.7

2 +22 +3.7/-5.2 +19 +4.7/-4.2

3 +23 +2.7/-5.2 +20 +3.7/-4.2

4 +22 +3.7/-5.2 +19 +4.7/-4.2

5 +24 +1.7/-6.7 +21 +2.7/-5.7




Figure 6(a): TPC configuration

Figure 6(b): TPC control configuration for Maximum Power




A HSUPA call is established. The UE power is set to be at least 7.5 dB lower than the maximum output power and wait for 150 ms. Configuration in R&S®CMU200: BS Signal Settings � TPC Pattern Setup � Set 1 Power control bits of one TPC_cmd = +1 command is sent to the UE. The received E-TFCI in UE is checked for 150 ms. If UE does not send decreased E-TFCI (DTX on E-DPDCH is also considered decreased E-TFCI) within 150 ms, TPC_cmd = +1 command is sent to the UE, wait for 150 ms and decreased E-TFCI is checked. This process is repeated until UE sends decreased E-TFCI. Configuration in R&S®CMU200: BS Signal Settings � TPC Pattern Setup � Set 2 BS Signal Settings � Activate Pattern Measurement result for E-TFCI is available in HSUPA E-AGCH in R&S®CMU200. Configuration in R&S®CMU200: Menus � Receiver Quality � Applic. 2 � HSUPA E-AGCH Figure 7(a) and 7(b) show the target E-TFCI (for sub-test 1) and decreased E-TFCI respectively. In Figure 7(b) value for decreased E-TFCI is E-TFCI 71. The value for decreased E-TFCI may vary depending on the UE output power.

Figure 7(a): Target E-TFCI transmitted by the UE




Figure 7(b): Decreased E-TFCI transmitted by the UE

Power control bits of one TPC_cmd = -1 command is sent to the UE and wait for 150 ms. The received E-TFCI is checked for 150ms. If UE sends any decreased E-TFCI (DTX on E-DPDCH is also considered decreased E-TFCI) within 150 ms, TPC_cmd = -1 command is sent to the UE and wait for 150 ms. Configuration in R&S®CMU200: BS Signal Settings � TPC Pattern Setup � Set 3 BS Signal Settings � Activate Pattern E-TFCI transmitted by the UE is verified and confirmed to be equal to the target E-TFCI in Table 5. UE is failed if the E-TFCI transmitted by the UE is not equal to the target E-TFCI. Mean power of the UE is measured. The maximum output power with HS-DPCCH and E-DCH is repeated with different combinations of β values as specified in Table 5. Measurement result for maximum output power with HS-DPCCH and E-DCH is available in Maximum Power in R&S®CMU200. Configuration in R&S®CMU200: Menu � Power � Application � Maximum Power Figure 8 shows the maximum output power measurement result.




Figure 8: Maximum output power with HS-DPCCH and E-DCH measurement result

Note: The limits for Maximum Power can be set in R&S®CMU200 according to Table 10. Configuration in R&S®CMU200: Maximum Power � Maximum Power � Limits � Maximum Power �Current&Max./Min. � UEPower(RMS) rated value, upper limit, lower limit Maximum Power � Maximum Power � Limits � Maximum Power � Average �UEPower(RMS) rated value, upper limit, lower limit








The TPC setting is available at: BS Signal Settings � TPC Pattern Setup � Set 1 (closed loop), Set 2 (TPC_cmd = +1 command) or Set 3 (TPC_cmd = -1 command) BS Signal Settings � Activate Pattern (for Set 2 and Set 3)

The measurement result is available at: Menus � Receiver Quality � Applic.2 � HSUPA E-AGCH Menus � Power � Application � Maximum Power


UE Relative Code Domain Power Accuracy for HS-DPCCH and E-DCH (5.2D)


2.3 UE Relative Code Domain Power Accuracy for HS-DPCCH and E-DCH (5.2D)

UE relative code domain power accuracy measures the ability of the UE to correctly set the level of individual code power relative to the total power of all active codes. The measure of accuracy is the difference between two dB ratios:

UE Relative CDP accuracy = (Measured CDP ratio) – (Nominal CDP ratio) where

=

codes active all ofpower total Measured power code Measured log*10ratio CDP Measured

=CDPs nominal all ofSum CDP Nominal log*10ratio CDP Nominal

The nominal CDP of a code is relative to the total of all codes and is derived from beta factors. The sum of all nominal CDPs will equal 1 by definition. The UE relative CDP accuracy shall be maintained over the period during which the total of all active code powers remains unchanged or one timeslot, whichever is the longer. This test applies to all FDD UE of Release 6 and later releases that support HSDPA and E-DCH. This test is in addition to the test for HSDPA only in 5.2C of TS 34.121 [1]. Figure 9 shows the transmit power profile for UE relative code domain power accuracy. A repeating pattern with alternating value of Absolute Grants as shown in Table 5 and Absolute Grant Index of Zero_Grant is generated. This will generate a repeating pattern on the E-DPDCH(s) with a level corresponding to the sending of Scheduling Information every other 10ms E-DCH TTI as shown in Figure 9. The relative code domain power of each active code is measured at the measurement points as specified in Figure 9. Each measurement is over a half slot period. Measurement point 1 is the last timeslot before TTI1. Measurement point 2 is the first timeslot of TTI1 and measurement point 3 is the first timeslot of TTI2. The 25 µs transient periods at the ends of each measured timeslot shall not be included.

TTI 1 10 ms

TTI 210ms

1

2

3

Figure 9: Transmit power profile showing measurement points (Figure 5.2D.1 of TS 34.121 [1]) Table 11 shows the nominal UE relative code domain power for each active code at each point. Table 12 shows the test requirements for the required accuracy, i.e. the difference between the expected and measured code domain power.




UE relative code domain power nominal ratios Expected relative code domain power in dB Subtest in

Table 5 Measurement

point DPCCH DPDCH HS-DPCCH E-DPCCH E-DPDCH1 E-DPDCH2

1 -9.3 -6.6 -3.3 -7.3 -18.9 OFF

2 -18.5 -15.8 -12.5 -16.5 -0.5 OFF 1

3 -9.3 -6.6 -3.3 -7.3 -18.9 OFF

1 -11.9 -3.9 -5.8 -5.8 -21.4 OFF

2 -14.0 -6.0 -8.0 -8.0 -4.1 OFF 2

3 -11.9 -3.9 -5.8 -5.8 -21.4 OFF

1 -9.8 -14.2 -3.7 -3.7 -19.3 OFF

2 -14.6 -19.1 -8.6 -8.6 -4.7 -4.7 3

3 -9.8 -14.2 -3.7 -3.7 -19.3 OFF

1 -17.9 -0.4 -11.9 -17.9 -27.5 OFF

2 -19.7 -2.2 -13.7 -19.7 -4.7 OFF 4

3 -17.9 -0.4 -11.9 -17.9 -27.5 OFF Table 11: UE relative code domain power nominal ratios (Table 5.2D.7 of TS 34.121 [1])

Table 12: UE relative code domain power accuracy test requirements (Table 5.2D.8 of TS 34.121 [1]) Fixed Reference Channels (FRC H-Set 1, QPSK version), RADIO BEARER SETUP message, sub-test 1, downlink physical channels, and serving cell are configured in R&S®CMU200 as specified in section 2.1 with exception of RADIO BEARER SETUP message in Table 13.

Table13: Contents of RADIO BEARER SETUP message: AM or UM (Test Loop Mode 1) (Table5.2D.2 and Table 5.13.2B.3 of TS 34.121 [1]) In 3GPP TS 34.121 V8.7.0, UE relative code domain power accuracy for HS-DPCCH and E-DCH is measured at UE power level of 15 dBm ± 2 dB. In 3GPP TS 34.121 V8.6.0 and previous releases, UE relative code domain power accuracy for HS-DPCCH and E-DCH is measured at maximum output power as specified in section 2.2. Configuration and *.sav file for this test case are based on TS 34.121 V8.7.0 [1].

UE relative code domain power accuracy test requirementsNominal CDP ratio Accuracy (dB)

≥ -10 dB ±1.7

-10 dB to ≥ -15 dB ±2.3

-15 dB to ≥ -20 dB ±2.9


UL Transport channel information for all transport channels

- 2 bit CTFC 3

- Power offset Information


- CHOICE mode FDD

- Gain factor ßc Value used in test: see Table 5

- Gain factor ßd Value used in test: see Table 5

Note: All other 2 bit CTFC values use computed gain factors as in the default message




A HSUPA call is established. The UE power is set to be 15 dBm ± 2 dB by referring to Figure 10. Configuration in R&S®CMU200: BS Signal Settings � TPC Pattern Config � TPC Pattern Set � Set 1 BS Signal Settings � TPC Pattern Config. � Set 1 � Pattern Type � Closed Loop BS Signal Settings � TPC Pattern Config. � Set 1 � UL Target Power � 15.0 dBm E-TFCI transmitted by the UE is verified and confirmed to be equal to the target E-TFCI in Table 5. UE is failed if the E-TFCI transmitted by the UE is not equal to the traget E-TFCI. Measurement result for E-TFCI is available in HSUPA E-AGCH in R&S®CMU200. Configuration in R&S®CMU200: Menus � Receiver Quality � Applic. 2 � HSUPA E-AGCH Figure 7(a) shows the E-TFCI transmitted by the UE. Alternating “0” and “1” TPC commands are sent in the downlink so as to satisfy the condition of obtaining TPC_cmd = 0. Configuration in R&S®CMU200: BS Signal Settings � TPC Pattern Config � TPC Pattern Set � Set 1 BS Signal Settings � TPC Pattern Config. � Set 1 � Pattern Type � Alternating 0, 1

Figure 10: Alternating “0” and “1” TPC pattern configuration




A repeating pattern with alternating value of Absolute Grants of sub-test 1 and Absolute Grant Index of Zero_Grant is generated. Configuration in R&S®CMU200: BS Signal � HSUPA � E-AGCH � AG Pattern � Pattern Length � 2BS Signal � HSUPA � E-AGCH � AG Pattern � AG Index � 0 20

Figure 11: E-AGCH AG pattern configuration The UE relative code domain power accuracy for HS-DPCCH and E-DCH is repeated with different combinations of β values for sub-test 2, 3 and 4 as specified in Table 5. Measurement result for UE relative code domain power accuracy with HS-DPCCH and E-DCH is available in CDP/Relative in R&S®CMU200. Configuration in R&S®CMU200: Menus � Code Dom. Power � Applic. 1 � CDP/Relative Figure 12(a) shows the UE relative code domain power accuracy for HS-DPCCH and E-DCH measurement result.




Figure 12(a): UE relative code domain power accuracy for HS-DPCCH and E-DCH measurement result It is recommended to use frame trigger for UE relative code domain power accuracy with HS-DPCCH and E-DCH. Configuration in R&S®CMU200: Trigger � Trigger Source � Frame The number of symbols displayed in the graph can be configured by changing the Measure Length in R&S®CMU200 as shown in Figure 12(b). Configuration in R&S®CMU200: Menus � Code Dom. Power � Applic. 1 � CDP/Relative CDP Relative � 40.0 Position of the measurement points can be configured by changing the Measure Points in R&S®CMU200. Configuration in R&S®CMU200: Menus � Code Dom. Power � Applic. 1 � CDP/Relative CDP/Relative � Measure Points � Measure Point 1 � 14.5 CDP/Relative � Measure Points � Measure Point 2 � 15.5 CDP/Relative � Measure Points � Measure Point 3 � 30.5 The upper diagram of the measurement result shows the UE-Power, which matches transmit power profile in Figure 8. The lower diagram can display either DPCCH, DPDCH1, HS-DPCCH, E-DPCCH, E-DPDCH1 or E-DPDCH2 by changing Diagram Type.




Configuration in R&S®CMU200: Menus � Code Dom. Power � Applic. 1 � CDP/Relative Diagram Type � DPCCH, DPDCH1, HS-DPCCH, E-DPCCH, E-DPDCH1 or E-DPDCH2

Figure 12(b): CDP Relative diagram configuration The span of X and Y scale of both diagrams can be configured by changing the Scale X and Scale Y in R&S®CMU200 as shown in Figure 14(b). Configuration in R&S®CMU200: Display � UE-Power Scale Y � 10 dBm Display � E-DPCCH Scale Y � 10 dB Display � UE-Power Scale X � Start � 0Display � UE-Power Scale X � Span � 40 Display � E-DPCCH Scale X � Start � 0Display � E-DPCCH Scale X � Span � 40




Figure 12(c): Span of X and Y scale configuration






For sub-test 3, recall HSUPATx3.sav and establish CS call. For sub-test 4, recall HSUPATx4.sav and establish CS call. E-DCH category 6

For sub-test 1, recall HSUPATx1.sav, modify the following configuration and establish PS call. UE Signal � HSUPA � Maximum Channelisation Code � 2xSF2 and 2xSF4 For sub-test 2, recall HSUPATx2.sav, modify the following configuration and establish PS call. UE Signal � HSUPA � Maximum Channelisation Code � 2xSF2 and 2xSF4 For sub-test 3, recall HSUPATx3.sav, modify the following configuration and establish PS call. UE Signal � HSUPA � Maximum Channelisation Code � 2xSF2 and 2xSF4 For sub-test 4, recall HSUPATx4.sav, modify the following configuration and establish PS call. UE Signal � HSUPA � Maximum Channelisation Code � 2xSF2 and 2xSF4

Modify the following configurations for all the above *sav files:BS Signal � HSUPA � E-AGCH � AG Pattern � Pattern Length � 2BS Signal � HSUPA � E-AGCH � AG Pattern � AG Index � 0 20 (sub-test 1), 0 12 (sub-test 2), 0 15 (sub-test 3), 0 17 (sub-test 4) Trigger � Trigger Source � Frame The TPC setting is available at: BS Signal Settings � TPC Pattern Setup � Set 1 (closed loop), Set 4 (Alternating 0, 1) The measurement result is available at: Menus � Receiver Quality � Applic.2 � HSUPA E-AGCH Menus � Code Dom. Power � CDP/Relative


Spectrum Emission Mask with E-DCH (5.9B)


2.4 Spectrum Emission Mask with E-DCH (5.9B) Spectrum emission mask of the UE applies to frequencies between 2.5 MHz and 12.5 MHz away from the UE centre carrier frequency. The out of channel emission is specified relative to the RRC filtered mean power of the UE carrier. This test applies to all FDD UE of Release 6 and later releases that support HSDPA and E-DCH. This test verifies that the power of UE emission does not exceed the limit in Table 14 even in the presence of the E-DCH for all values of βc, βd, βHS, βec and βed as specified in Table 5. The maximum output power with HS-DPCCH and/or E-DCH is specified in section 2.2. Excess emission increases the interference to other channels or to other systems. Table 14, 14(a), 14(b) and 14(c) show the spectrum emission mask requirement and additional spectrum emission limits. ∆f is the separation between the carrier frequency and the centre of the measurement bandwidth. The minimum requirement is calculated from the relative requirement or the absolute requirement, whichever is the higher power.

Spectrum Emission Mask Requirement Minimum requirement

∆f in MHz Relative requirement Absolute requirement

Measurement bandwidth

2.5 - 3.5 dBc 5.2MHz

f.155.33

−

∆−− -69.6 dBm 30 kHz

3.5 - 7.5 dBc 5.3MHz

f.15.33

−

∆−− -54.3 dBm 1 MHz

7.5 - 8.5 dBc 5.7MHz

f.105.37

−

∆−− -54.3 dBm 1 MHz

8.5 - 12.5 -47.5 dBc -54.3 dBm 1 MHz Table 14: Spectrum emission mask requirement (Table 5.9B.3 of TS 34.121 [1])

Additional spectrum emission limits for Bands II, IV, X ∆f in MHz Frequency offset of measurement

filter centre frequency, f_offset Additional requirements

Band II, IV, X Measurement bandwidth

2.5 MHz ≤ ∆f < 3.5 MHz 2.515 MHz ≤ f_offset < 3.485 MHz -15 dBm 30 kHz

3.5 MHz ≤ ∆f ≤ 12.5 MHz 4.0 MHz ≤ f_offset < 12.0 MHz -13 dBm 1 MHz Table 14(a): Additional spectrum emission limits for Bands II, IV, X (Table 5.9B.3A of TS 34.121 [1])

Additional spectrum emission limits for Band V ∆f in MHz Frequency offset of measurement


Band V Measurement bandwidth


3.5 MHz ≤ ∆f ≤ 12.5 MHz 3.55 MHz ≤ f_offset < 12.45 MHz -13 dBm 100 kHz Table 14(b): Additional spectrum emission limits for Bands V (Table 5.9B.3B of TS 34.121 [1])




Additional spectrum emission limits for Bands XII, XIII, XIV ∆f in MHz Frequency offset of measurement


Band XII, XIII, XIV Measurement bandwidth


2.6 MHz ≤ ∆f ≤ 12.45 MHz 2.65 MHz ≤ f_offset < 12.45 MHz -13 dBm 100 kHz Table 14(c): Additional spectrum emission limits for Bands XII, XIII, XIV (Table 5.9B.3C of TS 34.121 [1]) Fixed Reference Channels (FRC H-Set 1, QPSK version), RADIO BEARER SETUP message, sub-test 1, downlink physical channels, and serving cell are configured in R&S®CMU200 as specified in section 2.1. A HSUPA call is established. Maximum output power in UE is set as specified in section 2.2. The spectrum emission mask with E-DCH is repeated with different combination of βvalues as specified in Table 5. Measurement result for spectrum emission mask with E-DCH is available in Emission Mask in R&S®CMU200. Configuration in R&S®CMU200: Menus � Spectrum � Application � Emission Mask

Figure 13 shows the spectrum emission mask with E-DCH measurement result.

Figure 13: Spectrum emission mask measurement result









The measurement result is available at: Menus � Receiver Quality � Applic.2 � HSUPA E-AGCH Menus � Spectrum � Emission Mask


Adjacent Channel Leakage Power Ratio (ACLR) with E-DCH (5.10B)


2.5 Adjacent Channel Leakage Power Ratio (ACLR) with E-DCH (5.10B)

ACLR is defined as the ratio of the RRC filtered mean power centred on the assigned channel frequency to the RRC filtered mean power centred on an adjacent channel frequency. Excess ACLR increases the interference to other channels or to other systems. This test applies to all FDD UE of Release 6 and later releases that support HSDPA and E-DCH. This test verifies that the power of UE emission does not exceed the limit in Table 15 for all values of βc, βd and βHS, βec and βed as specified in Table 5. The maximum output power with E-DCH is specified in section 2.2. UE ACLR

Power Class UE channel ACLR limit

3 +5 MHz or −5 MHz 32.2 dB

3 +10 MHz or −10 MHz 42.2 dB

4 +5 MHz or −5 MHz 32.2 dB

4 +10 MHz or −10 MHz 42.2 dB Table 15: UE ACLR (Table 5.10B.2 of TS 34.121 [1]) Fixed Reference Channels (FRC H-Set 1, QPSK version), RADIO BEARER SETUP message, sub-test 1, downlink physical channels, and serving cell are configured in R&S®CMU200 as specified in section 2.1. A HSUPA call is established. Maximum output power in UE is set as specified in section 2.2. The ACLR with HS-DPCCH is repeated with different combination of β values as specified in Table 5. Measurement result for ACLR with E-DCH is available in ACLR Filter in R&S®CMU200. Configuration in R&S®CMU200: Menus � Spectrum � Application � ACLR Filter




Figure 14 shows the ACLR with E-DCH measurement result.

Figure 14: ACLR with E-DCH measurement result









The measurement result is available at: Menus � Receiver Quality � Applic.2 � HSUPA E-AGCH Menus � Spectrum � ACLR Filter


Relative Code Domain Error with HS-DPCCH and E-DCH (5.13.2B)


2.6 Relative Code Domain Error with HS-DPCCH and E-DCH (5.13.2B)

Relative code domain error for every non-zero beta code in the domain measures the ratio of the mean power of the projection onto the non-zero beta code to the mean power of the non-zero beta code in the composite reference waveform. The measurement interval is one timeslot except when the mean power between slots is expected to change, whereupon the measurement interval is reduced by 25 µs at each end of the slot. Relative code domain error is affected by both the spreading factor and beta values of the various code channels in the domain. Effective Code Domain Power (ECDP) for each used code k is defined using Nominal CDP ratio as specified in TS 25.101 [4]. ECDPk = (Nominal CDP ratio)k + 10 * log 10 (SFk / 256) Relative Code Domain Error is not applicable when either or both the following channel conditions occur:

i) ECDP of any code channel is < -30 dB ii) Nominal code domain power of any code channel is < -20 dB

Relative code domain error considers only code channels with non-zero beta in the composite reference waveform and does not apply to PRACH preamble and message parts. This test applies to all FDD UE of Release 6 and later releases that support HSDPA and E-DCH. Table 16, 17 and Table 18 show the parameters for relative code domain error with HS-DPCCH and E-DCH, nominal ECDP ratios and relative code domain error test requirement respectively. Relative code domain error shall meet the test requirements in Table 18 for parameters specified in Table 16. Parameters for relative code domain error with HS-DPCCH and E-DCH

Parameter Unit Level

UE output power dBm ≥ −20

Operating conditions Normal conditions

Power control step size dB 1

PRACH 3904 Measurement period1

Any DPCH Chips

From 1280 to 25602

Notes: 1. Less any 25 µs transient periods 2. The longest period over which the nominal power remains constant Table 16: Parameters for relative code domain error with HS-DPCCH and E-DCH (Table 5.13.2B.2 of TS 34.121 [1])




Nominal ECDP ratios Sub-test in Table 5 Code Nominal Code Domain Power Spreading factor Nominal ECDP

DPCCH -18.5 256 -18.5

DPDCH -15.8 64 -21.8

HS-DPCCH -12.5 256 -12.5

E-DPCCH -16.5 256 -16.5

1

E-DPDCH -0.5 4 -18.6

DPCCH -14.0 256 -14.0

DPDCH -6.0 64 -12.0

HS-DPCCH -8.0 256 -8.0

E-DPCCH -8.0 256 -8.0

2

E-DPDCH -4.1 4 -22.2

DPCCH -14.6 256 -14.6

DPDCH -19.1 64 -25.1

HS-DPCCH -8.6 256 -8.6

E-DPCCH -8.6 256 -8.6

E-DPDCH1 -4.7 4 -22.8

3

E-DPDCH2 -4.7 4 -22.8

DPCCH -19.7 256 -19.7

DPDCH -2.2 64 -8.2

HS-DPCCH -13.7 256 -13.7

E-DPCCH -19.7 256 -19.7

4

E-DPDCH -4.7 4 -22.8 Table 17: Nominal ECDP ratios (Table 5.13.2B.8 of TS 34.121 [1]) Relative code domain error test requirement

ECDP (dB) Relative code domain error (dB)

-21 < ECDP ≤ -15.5

-30 ≤ ECDP ≤ -21 ≤ -36.5 - ECDP

ECDP < -30 No requirement Table 18: Relative code domain error test requirement (Table 5.13.2B.9 of TS 34.121 [1]) Fixed Reference Channels (FRC H-Set 1, QPSK version), RADIO BEARER SETUP message, sub-test 1, downlink physical channels, and serving cell are configured in R&S®CMU200 as specified in section 2.1 with exception of RADIO BEARER SETUP message in Table 13. In 3GPP TS 34.121 V8.7.0, relative code domain error with HS-DPCCH and E-DCH is measured at UE power level of 15 dBm ± 2 dB and -18 dBm ± 2 dB. In 3GPP TS 34.121 V8.6.0 and previous releases, relative code domain error with HS-DPCCH and E-DCH is measured at maximum output power as specified in section 2.2 and -18 dBm ± 2 dB. Configuration and *.sav file for this test case are based on TS 34.121 V8.7.0 [1]. A HSUPA call is established. The UE power is set to be 15 dBm ± 2 dB by referring to Figure 10.




Configuration in R&S®CMU200: BS Signal Settings � TPC Pattern Config � TPC Pattern Set � Set 1 BS Signal Settings � TPC Pattern Config. � Set 1 � Pattern Type � Closed Loop BS Signal Settings � TPC Pattern Config. � Set 1 � UL Target Power � 15.0 dBm E-TFCI transmitted by the UE is verified and confirmed to be equal to the target E-TFCI in Table 5. UE is failed if the E-TFCI transmitted by the UE is not equal to the traget E-TFCI. Measurement result for E-TFCI is available in HSUPA E-AGCH in R&S®CMU200. Configuration in R&S®CMU200: Menus � Receiver Quality � Applic. 2 � HSUPA E-AGCH Figure 7(a) shows the E-TFCI transmitted by the UE. The relative code domain error measurement is repeated with UE power level of -18 dBm with ±2 dB tolerance. These settings can be configured in R&S®CMU200 by referring to Figure 10. Configuration in R&S®CMU200: BS Signal Settings � Set 1 � Pattern Type � Closed Loop BS Signal Settings � Set 1 � UL Target Power � -18.0 dBm The relative code domain error measurement is repeated with different combinations of β values for sub-test 2, 3 and 4 as specified in Table 5 at UE power level of 15 dBm ±2 dB and -18 dBm with ±2 dB tolerance.

Measurement result for relative code domain error with HS-DPCCH and E-DCH is available in CDE Relative in R&S®CMU200. Configuration in R&S®CMU200: Menus � Code Dom. Power � Applic. 2 � CDE/Relative




Figure 15 shows the relative code domain error with HS-DPCCH and E-DCH measurement result.

Figure 15: Relative code domain error with HS-DPCCH and E-DCH measurement result It is recommended to use frame trigger for UE relative code domain power accuracy with HS-DPCCH and E-DCH. Configuration in R&S®CMU200: Trigger � Trigger Source � Frame Depending on the values of gain factors, measurement threshold may require adjustment. Configuration in R&S®CMU200: UE Signal � Measurement Settings � Threshold � -10 dB




Figure 16: Measurement threshold configuration






For sub-test 3, recall HSUPATx3.sav and establish CS call. For sub-test 4, recall HSUPATx4.sav and establish CS call. E-DCH category 6

For sub-test 1, recall HSUPATx1.sav, modify the following configuration and establish PS call. UE Signal � HSUPA � Maximum Channelisation Code � 2xSF2 and 2xSF4 For sub-test 2, recall HSUPATx2.sav, modify the following configuration and establish PS call. UE Signal � HSUPA � Maximum Channelisation Code � 2xSF2 and 2xSF4 For sub-test 3, recall HSUPATx3.sav, modify the following configuration and establish PS call. UE Signal � HSUPA � Maximum Channelisation Code � 2xSF2 and 2xSF4 For sub-test 4, recall HSUPATx4.sav, modify the following configuration and establish PS call. UE Signal � HSUPA � Maximum Channelisation Code � 2xSF2 and 2xSF4

Modify the following configuration for all the above *sav files:Trigger � Trigger Source � Frame The TPC setting is available at: BS Signal Settings � TPC Pattern Setup � Set 1 BS Signal Settings � Set 1 � UL Target Power � 15.0 dBm or -18.0 dBm The measurement result is available at: Menus � Receiver Quality � Applic.2 � HSUPA E-AGCH Menus � Code Dom. Power � Applic. 2 � CDE/Relative

Rel-6 Performance Requirements

Generic Call Setup for Performance Requirements


3 Rel-6 Performance Requirements

3.1 Generic Call Setup for Performance Requirements All parameters of performance requirements are defined using the UL reference measurement channel (RMC) 12.2 kbps and Fixed Reference Channels (FRC H-Set 1, QPSK) as specified in TS 34.121 Annex C.11 unless stated otherwise. Loopback test mode 1 as specified in 5.3.2.3 and 5.3.2.6 of TS 34.109 [2] is used for looping back both the 12.2 kbps RMC and HSDPA to E-DCH. E-DCH call is setup according to 7.3.9 of TS 34.108 [3]. Table 2 shows the UL RLC SDU size for E-DCH performance requirements supported by R&S®CMU200. A HSUPA call is configured in R&S®CMU200 as shown in Figure 1(a) and 1(b). UE output power for all performance requirements shall be greater than -10 dBm unless stated otherwise. Configuration in R&S®CMU200: BS Signal � TPC Settings � TPC Algorithm � Algorithm 1 BS Signal � TPC Settings � TPC Step Size � 1 dB BS Signal � TPC Settings � TPC Pattern Setup � Set 1 BS Signal � TPC Settings � Set 1 � Pattern Type � Closed Loop BS Signal � TPC Settings � Set 1 � UL Target Power � 0.0 dBm UL RLC SDU size is configured in R&S®CMU200 according to Table 2. Configuration in R&S®CMU200: BS Signal � Circuit Switched � RMC Settings � HSPA � HSUPA UL RLC SDU Size � 2936 Bit (for section 3.2, 3.3, 3.6 and 3.7) or 5872 Bit (for section 3.4, 3.5, 3.8 and 3.9) or 8808 Bit (for section 3.10 and 3.11)

RADIO BEARER SETUP message in 9.2.1 of TS 34.108 [3] as shown in Table 19 and Table 20 are used to configure E-DCH call.

Table 19: Contents of RADIO BEARER SETUP message: AM or UM (Test Loop Mode 1) (Subset of 9.2.1 of TS 34.108 [3])

Contents of RADIO BEARER SETUP message: AM or UM (Test Loop Mode 1) Information Element Condition Value/remark Version

- Power offset information


- CHOICE mode FDD

- Gain factor βc 8

- Gain factor βd 15




Notes: Condition A1: not using E-DCH 4 codes Condition A2: using E-DCH 4 codes Table 20: Contents of RADIO BEARER SETUP message: AM or UM (E-DCH and HSDPA) (Subset of 9.2.1 of TS 34.108 [3])

Contents of RADIO BEARER SETUP message: AM or UM (E-DCH and HSDPA) Information Element Condition Value/remark Version

- RLC PDU size 336 bits

CHOICE channel requirement Uplink DPCH info Rel-5 and earlier Rel-6

- Power Control Algorithm Algorithm1

- TPC step size 0 (1 dB)

- ∆ACK 3

- ∆NACK 3

- Ack-Nack repetition factor 1

E-DCH info A1, A2

- E-DPCCH info

- Happy bit delay condition 100 ms

- E-DPDCH info A1



- Reference E-TFCIs 1 E-TFCI



- Maximum channelisation codes 2sf4

- PLnon-max 0.84

- E-DPDCH info A2



- Reference E-TFCIs 2 E-TFCI





- Maximum channelisation codes 2sf2 and 2sf4

- PLnon-max 0.84

Downlink HS-PDSCH Information

- Measurement Feedback Info

- CHOICE mode FDD

- CQI Feedback cycle, k 2 ms

- CQI repetition factor 1

- ∆CQI 5 (corresponds to 0 dB in relative power offset)

- Scheduled Transmission configuration A1, A2 - 2 ms scheduled transmission grant

HARQ process allocation Not present

- Serving Grant Not present




Configuration in R&S®CMU200: BS Signal � HSUPA � RLC PDU Size � 336 BS Signal � HSDPA HS-DSCH � CQI Feedback Cycle � 2 ms BS Signal � HSDPA HS-DSCH � CQI Repetition Factor � 1BS Signal � HSDPA HS-DSCH � ACK/NACK Repetition Factor � 1BS Signal � HSDPA HS-DSCH � Channel Configuration Type � Fixed Reference Channel BS Signal � HSDPA HS-DSCH � Fixed Reference Channel � H-Set Selection � H-Set 1 QPSK UE Signal � HSUPA � E-TFCI Table Index � 0UE Signal � HSUPA � Minimum Set E-TFCI � 9UE Signal � HSUPA � Happy Bit Delay Condition � 100 ms UE Signal � HSUPA � Puncturing Limit PLnon-max � 0.84 UE Signal � HSUPA � Maximum Channelisation Code � 2xSF4 (for E-DCH category 1 to 5) or 2xSF2 and 2xSF4 (for E-DCH category 6) UE Signal � HSUPA � Initial Serving Grant � Value � Off UE Signal � HSUPA � HSUPA Gain Factors � Number of Reference E-TFCIs � 1(for E-DCH category 1 to 5) or 2 (for E-DCH category 6) UE Signal � HSUPA � Reference E-TFCI 1…4 � 11 (for E-DCH category 1 to 5) or 11 83 (for E-DCH category 6) UE Signal � HSUPA � Reference E-TFCI Power Offset � 4 (for E-DCH category 1 to 5) or 4 16 (for E-DCH category 6) UE Signal � UE Gain Factors � Packet Data � HSDPA / HSUPA � βc � 8UE Signal � UE Gain Factors � Packet Data � HSDPA / HSUPA � βd � 15 UE Signal � UE Gain Factors � Packet Data � HSDPA / HSUPA � ∆ACK � 3UE Signal � UE Gain Factors � Packet Data � HSDPA / HSUPA � ∆NACK � 3UE Signal � UE Gain Factors � Packet Data � HSDPA / HSUPA � ∆CQI � 5

These settings can be configured in R&S®CMU200 by referring to Figure 2(a), 2(b), 2(c) and 3(a). Table 21 shows the downlink physical channels for E-DCH single link performance tests for subclauses 10.2.1, 10.3.1, 10.4.1 and 10.4.1A as specified in Table E.5A.2 of TS 34.121 [1].




Notes: 1. During TTIs, in which the HS-PDSCH is not allocated to the UE via HS-SCCH signalling, the HS-PDSCH

shall be transmitted continuously with constant power 2. During TTIs, in which the HS-SCCH is not allocated to the UE the HS-SCCH shall be transmitted

continuously with constant power. 3. Test specific value or -20 dB is used 4. Test specific value or DTX’d is used. Table 21: Downlink physical channel parameters for E-DCH single link performance tests (Table E.5A.2 of TS 34.121 [1]) Configuration in R&S®CMU200: BS Signal � Node-B Settings � Level Reference � Output Channel Power (Ior) BS Signal � Downlink Physical Channels � P-CPICH � -10.0 dB BS Signal � Downlink Physical Channels � P-SCH � -15.0 dB BS Signal � Downlink Physical Channels � S-SCH � -15.0 dB BS Signal � Downlink Physical Channels � P-CCPCH � -12.0 dB BS Signal � Downlink Physical Channels � PICH � -15.0 dB BS Signal � Downlink Physical Channels � DPDCH Level Config � -10.0 dB BS Signal � Downlink Physical Channels � HSDPA Channels � On BS Signal � Downlink Physical Channels � HS-SCCH � HS-SCCH#1 � Level �-7.5 dB BS Signal � Downlink Physical Channels � HS-SCCH � HS-SCCH#2 � Level � Off BS Signal � Downlink Physical Channels � HS-SCCH � HS-SCCH#3 � Level � Off BS Signal � Downlink Physical Channels � HS-SCCH � HS-SCCH#4 � Level � Off BS Signal � Downlink Physical Channels � HS-SCCH � HS-SCCH Selection � 1BS Signal � Downlink Physical Channels � HS-SCCH � Number of HS-SCCH � 4BS Signal � Downlink Physical Channels � HS-SCCH � Unscheduled Subframes �Transmit Dummy UEID BS Signal � Downlink Physical Channels � HS-PDSCH � Level (All Active Codes) � -3.0 dB BS Signal � Downlink Physical Channels � HSUPA Channels � On BS Signal � Downlink Physical Channels � E-AGCH � E-AGCH � -20.0 dB BS Signal � Downlink Physical Channels � E-RGCH/E-HICH � E-RGCH/E-HICH �Test specific value BS Signal � Downlink Physical Channels � E-RGCH Active � OFF or On (for E-RGCH test specific value) These settings can be configured in R&S®CMU200 by referring to Figure 2(a), 2(b), 2(c) and 3(a).

Downlink physical channel parameters for E-DCH single link performance tests Parameter during measurement Unit Value

P-CPICH_Ec/Ior dB -10

P-CCPCH and SCH_Ec/Ior dB -12

PICH_Ec/Ior dB -15

HS-PDSCH dB -3 (Note 1)

HS-SCCH_1 dB -7.5 (Note 2)

DPCH_Ec/Ior dB -10

E-AGCH dB Test specific (Note 3)

E-HICH dB Test specific (Note 4)

E-RGCH dB Test specific (Note 4)

OCNS_Ec/Ior dB Necessary power so that total transmit power spectral density of Node B (Ior) adds to one




The value of absolute grant scope shall be set to 0 (“All HARQ Processes”). Configuration in R&S®CMU200: BS Signal � HSUPA � E-AGCH � AG Pattern � AG Scope(√:Per HARQ proc.) �(unchecked) This setting can be configured in R&S®CMU200 as shown in Figure 3(b). All parameters of performance requirements in this application note require an external multi-path fading simulator, e.g. R&S®SMU200A, to generate VA30 multi-path fading signal. These tests are recommended to be performed remotely. Detail setup information on R&S®SMU200A and remote control via CMUgo are available in application note [6]. A HSUPA call is setup according to TS 34.108 [3] subclause 7.3.9. To establish a HSUPA connection, press ‘Connect UE (CS)’ (E-DCH category 1 to 5) or ‘Connect UE (PS)’ (E-DCH category 6) on R&S®CMU200 once UE has registered/attached with R&S®CMU200.


Detection of E-DCH HARQ ACK Indicator Channel (E-HICH): Single Link Performance (10 ms TTI) (10.2.1.1)


3.2 Detection of E-DCH HARQ ACK Indicator Channel (E-HICH): Single Link Performance (10 ms TTI) (10.2.1.1)

The receive characteristics of the E-DCH HARQ ACK Indicator Channel (E-HICH) in different multi-path fading environments are determined by the Missed ACK and False ACK values. The test will verify the average probability for Missed ACK and False ACK, when E-HICH is transmitted using 12 consecutive slots, do not exceed the specified values. The test applies to all FDD UE of Release 6 and later releases that support HSDPA and E-DCH. Upon the UE transmission on E-DPCCH and E-DPDCH, the SS (System Simulator, i.e. Node-B simulator) reacts with E-HICH = ACK or DTX. The UE transmits new data or retransmissions on the corresponding E-DPCCH and E-DPDCH. New data is a sign for ACK, received by the UE, while retransmission is a sign for NACK or DTX, received by the UE . The later is interpreted as NACK by higher layer and causes retransmission. Fixed Reference Channels (FRC H-Set 1, QPSK version), RADIO BEARER SETUP message as specified in section 3.1 is configured in R&S®CMU200 with exception of RADIO BEARER SETUP message in Table 22. External multi-path fading simulator is configured with VA30 fading signal.

Table 22: RADIO BEARER SETUP: Specific Message Contents (Section 10.2.1.1.4.2 and section 10.2.1.1A.4.2 of TS 34.121 [1])

Configuration in R&S®CMU200: BS Signal � HSUPA � TTI Mode � 10 ms BS Signal � HSUPA � RLC PDU Size � 112 UE Signal � HSUPA � Happy Bit Delay Condition � 10 ms UE Signal � HSUPA � RAB H-ARQ Profile � Max. Number of Retransmission � 15 These settings can be configured in R&S®CMU200 by referring to Figure 2(b) and 3(b). Table 23, 24 and 25 show the test parameters for E-HICH – serving E-DCH cell, test requirement for Missed ACK when hybrid ARQ acknowledgement indicator is transmitted using 12 consecutive slots – serving E-DCH cell and test requirement for False ACK when hybrid ARQ acknowledgement indicator is transmitted using 12 consecutive slots – single link respectively.

RADIO BEARER SETUP: Specific Message Contents Information Element Value/remark

RLC PDU size 112


E-DCH MAC-d flow maximum number of retransmissions 15 (max)

E-DCH info

- Happy bit delay condition 10 ms (indication of exhausted resources on frame basis)




Test parameters for E-HICH – Serving E-DCH cell Parameter Unit Missed ACK False ACK

Ioc dBm/3.84 MHz -60

Phase reference - P-CPICH

E-HICH Ec/Ior dB -35 (test 1) -∞ (test 2)

E-HICH signalling pattern - 100% ACK 100% DTX Table 23: Test parameters for E-HICH – Serving E-DCH cell (Table 10.2.1.1.5.1 of TS 34.121 [1])

Test requirement for Missed ACK when hybrid ARQ acknowledgement indicator is transmitted using 12 consecutive slots – Serving E-DCH cell

Reference Value Test Number Propagation

Conditions E-HICH Ec/Ior (dB) Ior/Ioc (dB) Missed ACK probability

1 VA30 -35.0 0.6 0.01 Table 24: Test requirement for Missed ACK when hybrid ARQ acknowledgement indicator is transmitted using 12 consecutive slots – Serving E-DCH cell (Table 10.2.1.1.5.2 of TS 34.121 [1])

Test requirement for False ACK when hybrid ARQ acknowledgement indicator is transmitted using 12 consecutive slots – Single link


Conditions Ior/Ioc (dB) False ACK probability

2 VA30 0.6 0.5 Table 25: Test requirement for False ACK when hybrid ARQ acknowledgement indicator is transmitted using 12 consecutive slots – Single link (Table 10.2.1.1.5.3 of TS 34.121 [1])

Downlink physical channels in section 3.1, Table 23, Table 24 and Table 25 are configured in R&S®CMU200. The Absolute Grant is set to 5. The Relative Grant is not configured. The expected UL data rate is 71.6 kbps corresponding to E-TFC Index 45. Configuration in R&S®CMU200: BS Signal � Node-B Settings � Output Channel Power (Ior) � -59.4 dBm BS Signal � Node-B Settings � AWGN Noise Pwr. (@3.84 MHz, Ioc) � Off BS Signal � HSUPA � E-AGCH � AG Pattern � AG Index � 5BS Signal � Downlink Physical Channels � E-RGCH/E-HICH � E-RGCH/E-HICH �-35.0 dB BS Signal � Downlink Physical Channels � E-RGCH/E-HICH � E-RGCH Active �Off These settings can be configured in R&S®CMU200 by referring to Figure 3(b), 5(a) and 5(e). A HSUPA call is established. Fading simulator is switched on. Missed ACK test:For Missed ACK, the SS responds with 100% ACK. If UE indicates on the E-DPCCH a retransmission, the ACK from the SS was received as NACK or DTX by the UE and is counted as missed ACK. If the UE indicates on the E-DPCCH new data, the ACK from the SS was received as ACK by the UE and is counted as correct ACK. If the number of retransmission reaches the maximum number of retransmission due to several false or missed ACK detections in series, the first new data on the E-DPDCH with E-DPCCH are not the consequence of ACK and this case is not counted as sample.




Configuration in R&S®CMU200: BS Signal � HSUPA � E-RGCH/E-HICH � HARQ Feedback (E-HICH) � Mode �All ACK

Figure 17: E-HICH configuration The test is continued until statistical significance as specified in Table F.6.4 of TS 34.121 [1] is achieved. False ACK test:For False ACK, the SS responds with 100% DTX. If UE indicates on the E-DPCCH new data, the DTX from the SS was received as ACK by the UE and is counted as false ACK. If the UE indicats on the E-DPCCH retransmission, the DTX from the SS was received as DTX or NACK by the UE and is counted as correct reception. The number of retranmission will reach the maximum number of retransmission due to several retransmissions in series. The first new data on the E-DPDCH with E-DPCCH are not the consequence of ACK received by the UE and this case is not counted as sample. Configuration in R&S®CMU200: BS Signal � HSUPA � E-RGCH/E-HICH � HARQ Feedback (E-HICH) � Mode �All DTX This setting can be configured in R&S®CMU200 by referring to Figure 17. The test is continued until statistical significance as specified in Table F.6.4 of TS 34.121 [1] is achieved. Measurement result for detection of E-DCH HARQ Indicator Channel (E-HICH) is available in HSUPA E-HICH in R&S®CMU200.




Configuration in R&S®CMU200: Menus � Receiver Quality � Applic. 2 � HSUPA E-HICH Figure 18 shows the detection of E-DCH HARQ Indicator Channel (E-HICH) measurement result.

Figure 18: Detection of E-DCH HARQ Indicator Channel (E-HICH) measurement result


For Missed ACK, recall EHICH10.sav and establish CS call. For False ACK, recall EHICH10.sav, modify the following configuration and establish CS call: BS Signal � HSUPA � E-RGCH/E-HICH � HARQ Feedback (E-HICH) � Mode �All DTX E-DCH category 6

For Missed ACK, recall EHICH10.sav, modify the following configuration and establish PS call. UE Signal � HSUPA � Maximum Channelisation Code � 2xSF2 and 2xSF4 For False ACK, recall EHICH10.sav, modify the following configurations and establish PS call. UE Signal � HSUPA � Maximum Channelisation Code � 2xSF2 and 2xSF4 BS Signal � HSUPA � E-RGCH/E-HICH � HARQ Feedback (E-HICH) � Mode �All DTX The measurement result is available at: Menus � Receiver Quality � Applic. 2 � HSUPA E-HICH


Detection of E-DCH HARQ ACK Indicator Channel (E-HICH): Single Link Performance (10 ms TTI, Type 1) (10.2.1.1A)


3.3 Detection of E-DCH HARQ ACK Indicator Channel (E-HICH): Single Link Performance (10 ms TTI, Type 1) (10.2.1.1A)

The receive characteristics of the E-DCH HARQ ACK Indicator Channel (E-HICH) in different multi-path fading environments are determined by the Missed ACK values. The test will verify the average probability for Missed ACK, when E-HICH is transmitted using 12 consecutive slots, do not exceed the specified values. The test applies to all FDD UE of Release 7 and later releases that support HSDPA and E-DCH and the optional Type 1 enhanced performance requirements. Upon the UE transmission on E-DPCCH and E-DPDCH, the SS (System Simulator, i.e. Node-B simulator) reacts with E-HICH = ACK. The UE transmits new data or retransmissions on the corresponding E-DPCCH and E-DPDCH. New data is a sign for ACK, received by the UE while retransmission is a sign for NACK or DTX, received by the UE . The later is interpreted as NACK by higher layer and causes retransmission. Fixed Reference Channels (FRC H-Set 1, QPSK version), RADIO BEARER SETUP message as specified in section 3.1 is configured in R&S®CMU200 with exception of RADIO BEARER SETUP message in Table 22. External multi-path fading simulator is configured with VA30 fading signal. Configuration in R&S®CMU200: BS Signal � HSUPA � TTI Mode � 10 ms BS Signal � HSUPA � RLC PDU Size � 112 UE Signal � HSUPA � Happy Bit Delay Condition � 10 ms UE Signal � HSUPA � RAB H-ARQ Profile � Max. Number of Retransmission � 15 These settings can be configured in R&S®CMU200 by referring to Figure 2(b) and 3(b). Table 26 and 27 show the test parameters for E-HICH – serving E-DCH cell and test requirement type 1 for Missed ACK when hybrid ARQ acknowledgement indicator is transmitted using 12 consecutive slots – serving E-DCH cell respectively.

Test parameters for E-HICH – Serving E-DCH cell Parameter Unit Missed ACK



E-HICH Ec/Ior dB -38.2 (test 1)

E-HICH signalling pattern - 100% ACK Table 26: Test parameters for E-HICH – Serving E-DCH cell (Table 10.2.1.1A.5.1 of TS 34.121 [1])




Test requirement Type 1 for Missed ACK when hybrid ARQ acknowledgement indicator is transmitted using 12 consecutive slots – Serving E-DCH cell



1 VA30 -38.2 0.6 0.01 Table 27: Test requirement Type 1 for Missed ACK when hybrid ARQ acknowledgement indicator is transmitted using 12 consecutive slots – Serving E-DCH cell (Table 10.2.1.1A.5.2 of TS 34.121 [1])

Downlink physical channels in section 3.1, Table 26 and Table 27 are configured in R&S®CMU200. The Absolute Grant is set to 5. The Relative Grant is not configured. The expected UL data rate is 71.6 kbps corresponding to E-TFC Index 45. Configuration in R&S®CMU200: BS Signal � Node-B Settings � Output Channel Power (Ior) � -59.4 dBm BS Signal � Node-B Settings � AWGN Noise Pwr. (@3.84 MHz, Ioc) � Off BS Signal � HSUPA � E-AGCH � AG Pattern � AG Index � 5BS Signal � Downlink Physical Channels � E-RGCH/E-HICH � E-RGCH/E-HICH �-38.2 dB BS Signal � Downlink Physical Channels � E-RGCH/E-HICH � E-RGCH Active �Off These settings can be configured in R&S®CMU200 by referring to Figure 3(b), 5(a) and 5(e). A HSUPA call is established. Fading simulator is switched on. For Missed ACK, the SS responds with 100% ACK. If UE indicates on the E-DPCCH a retransmission, the ACK from the SS was received as NACK or DTX by the UE and is counted as missed ACK. If the UE indicates on the E-DPCCH new data, the ACK from the SS was received as ACK by the UE and is counted as correct ACK. If the number of retransmission reaches the maximum number of retransmission due to several false or missed ACK detections in series, the first new data on the E-DPDCH with E-DPCCH are not the consequence of ACK and this case is not counted as sample. Configuration in R&S®CMU200: BS Signal � HSUPA � E-RGCH/E-HICH � HARQ Feedback (E-HICH) � Mode �All ACK This setting can be configured in R&S®CMU200 by referring to Figure 17. The test is continued until statistical significance as specified in Table F.6.4 of TS 34.121 [1] is achieved. Measurement result for detection of E-DCH HARQ Indicator Channel (E-HICH) is available in HSUPA E-HICH in R&S®CMU200. Configuration in R&S®CMU200: Menus � Receiver Quality � Applic. 2 � HSUPA E-HICH Figure 18 shows the detection of E-DCH HARQ Indicator Channel (E-HICH) measurement result.





Recall EHICH10.sav, modify the following configuration and establish CS call. BS Signal � Downlink Physical Channels � E-RGCH/E-HICH � E-RGCH/E-HICH � -38.2 dB E-DCH category 6

For Missed ACK, recall EHICH10.sav, modify the following configuration and establish PS call. UE Signal � HSUPA � Maximum Channelisation Code � 2xSF2 and 2xSF4 BS Signal � Downlink Physical Channels � E-RGCH/E-HICH � E-RGCH/E-HICH � -38.2 dB

The measurement result is available at: Menus � Receiver Quality � Applic. 2 � HSUPA E-HICH




3.4 Detection of E-DCH HARQ ACK Indicator Channel (E-HICH): Single Link Performance (2 ms TTI) (10.2.1.2)

The receive characteristics of the E-DCH HARQ ACK Indicator Channel (E-HICH) in different multi-path fading environments are determined by the Missed ACK and False ACK values. The test will verify the average probability for Missed ACK and False ACK, when E-HICH is transmitted using 3 consecutive slots, do not exceed the specified values. The test applies to all FDD UE of Release 6 and later releases that support HSDPA and E-DCH with 2 ms TTI. Upon the UE transmission on E-DPCCH and E-DPDCH, the SS (System Simulator, i.e. Node-B simulator) reacts with E-HICH = ACK or DTX. The UE transmits new data or retransmissions on the corresponding E-DPCCH and E-DPDCH. New data is a sign for ACK, received by the UE while retransmission is a sign for NACK or DTX, received by the UE . The later is interpreted as NACK by higher layer and causes retransmission. Fixed Reference Channels (FRC H-Set 1, QPSK version), RADIO BEARER SETUP message as specified in section 3.1 is configured in R&S®CMU200 with exception of RADIO BEARER SETUP message in Table 28. External multi-path fading simulator is configured with VA30 fading signal.

Table 28: RADIO BEARER SETUP: Specific Message Contents (Section 10.2.1.2.4.2 and section 10.2.1.2A.4.2 of TS 34.121 [1])

Configuration in R&S®CMU200: BS Signal � Packet Switched � HSUPA Test Mode � HSUPA UL RLC SDU Size �5872 Bit BS Signal � HSUPA � TTI Mode � 2 ms BS Signal � HSUPA � RLC PDU Size � 112 UE Signal � HSUPA � Happy Bit Delay Condition � 2 ms UE Signal � HSUPA � RAB H-ARQ Profile � Max. Number of Retransmission � 15 These settings can be configured in R&S®CMU200 by referring to Figure 1(b), 2(b) and 3(b). Table 29, 30 and 31 show the test parameters for E-HICH – serving E-DCH cell, test requirement for Missed ACK when hybrid ARQ acknowledgement indicator is transmitted using 3 consecutive slots – serving E-DCH cell and test requirement for False ACK when hybrid ARQ acknowledgement indicator is transmitted using 3 consecutive slots – serving E-DCH cell respectively.


RLC PDU size 112


E-DCH MAC-d flow maximum number of retransmissions 15 (max)

E-DCH info





Test parameters for E-HICH – Serving E-DCH cell Parameter Unit Missed ACK False ACK



E-HICH Ec/Ior dB -28.2 (test 1) -∞ (test 2)

E-HICH signalling pattern - 100% ACK 100% DTX Table 29: Test parameters for E-HICH – Serving E-DCH cell (Table 10.2.1.2.5.1 of TS 34.121 [1])

Test requirement for Missed ACK when hybrid ARQ acknowledgement indicator is transmitted using 3 consecutive slots – Serving E-DCH cell



1 VA30 -28.2 0.6 0.01 Table 30: Test requirement for Missed ACK when hybrid ARQ acknowledgement indicator is transmitted using 3 consecutive slots – Serving E-DCH cell (Table 10.2.1.2.5.2 of TS 34.121 [1])

Test requirement for False ACK when hybrid ARQ acknowledgement indicator is transmitted using 3 consecutive slots – Serving E-DCH cell


Conditions Ior/Ioc (dB) False ACK probability

2 VA30 0.6 0.5 Table 31: Test requirement for False ACK when hybrid ARQ acknowledgement indicator is transmitted using 3 consecutive slots – Serving E-DCH cell (Table 10.2.1.2.5.3 of TS 34.121 [1])

Downlink physical channels in section 3.1, Table 29, Table 30 and Table 31 are configured in R&S®CMU200. The Absolute Grant is set to 4. The Relative Grant is not configured. The expected UL data rate is 237 kbps corresponding to E-TFC Index 39. Configuration in R&S®CMU200: BS Signal � Node-B Settings � Output Channel Power (Ior) � -59.4 dBm BS Signal � Node-B Settings � AWGN Noise Pwr. (@3.84 MHz, Ioc) � Off BS Signal � HSUPA � E-AGCH � AG Pattern � AG Index � 4BS Signal � Downlink Physical Channels � E-RGCH/E-HICH � E-RGCH/E-HICH �-28.2 dB BS Signal � Downlink Physical Channels � E-RGCH/E-HICH � E-RGCH Active �Off These settings can be configured in R&S®CMU200 by referring to Figure 3(b), 5(a) and 5(e). A HSUPA call is established. Fading simulator is switched on. Missed ACK test:For Missed ACK, the SS responds with 100% ACK. If UE indicates on the E-DPCCH a retransmission, the ACK from the SS was received as NACK or DTX by the UE and is counted as missed ACK. If the UE indicates on the E-DPCCH new data, the ACK from the SS was received as ACK by the UE and is counted as correct ACK. If the number of retransmission reaches the maximum number of retransmission due to several false or missed ACK detections in series, the first new data on the E-DPDCH with E-DPCCH are not the consequence of ACK and this case is not counted as sample.




Configuration in R&S®CMU200: BS Signal � HSUPA � E-RGCH/E-HICH � HARQ Feedback (E-HICH) � Mode �All ACK This setting can be configured in R&S®CMU200 by referring to Figure 17. The test is continued until statistical significance as specified in Table F.6.4 of TS 34.121 [1] is achieved. False ACK test:For False ACK, the SS responds with 100% DTX. If UE indicats on the E-DPCCH new data, the DTX from the SS was received as ACK by the UE and is counted as false ACK. If the UE indicats on the E-DPCCH retransmission, the DTX from the SS was received as DTX or NACK by the UE and is counted as correct reception. The number of retranmission will reach the maximum number of retransmission due to several retransmissions in series. The first new data on the E-DPDCH with E-DPCCH are not the consequence of ACK received by the UE and this case is not counted as sample. Configuration in R&S®CMU200: BS Signal � HSUPA � E-RGCH/E-HICH � HARQ Feedback (E-HICH) � Mode �All DTX This setting can be configured in R&S®CMU200 by referring to Figure 17. The test is continued until statistical significance as specified in Table F.6.4 of TS 34.121 [1] is achieved. Measurement result for detection of E-DCH HARQ Indicator Channel (E-HICH) is available in HSUPA E-HICH in R&S®CMU200. Configuration in R&S®CMU200: Menus � Receiver Quality � Applic. 2 � HSUPA E-HICH Figure 18 shows the detection of E-DCH HARQ Indicator Channel (E-HICH) measurement result.




E-DCH category 2 and 4

For Missed ACK, recall EHICH2.sav and establish CS call. For False ACK, recall EHICH2.sav, modify the following configuration and establish CS call. BS Signal � HSUPA � E-RGCH/E-HICH � HARQ Feedback (E-HICH) � Mode �All DTX E-DCH category 6

For Missed ACK, recall EHICH2.sav, modify the following configuration and establish PS call. UE Signal � HSUPA � Maximum Channelisation Code � 2xSF2 and 2xSF4 For False ACK, recall EHICH2.sav, modify the following configurations and establish PS call. UE Signal � HSUPA � Maximum Channelisation Code � 2xSF2 and 2xSF4 BS Signal � HSUPA � E-RGCH/E-HICH � HARQ Feedback (E-HICH) � Mode �All DTX





3.5 Detection of E-DCH HARQ ACK Indicator Channel (E-HICH): Single Link Performance (2 ms TTI, Type 1) (10.2.1.2A)

The receive characteristics of the E-DCH HARQ ACK Indicator Channel (E-HICH) in different multi-path fading environments are determined by the Missed values. The test will verify the average probability for Missed ACK, when E-HICH is transmitted using 3 consecutive slots, do not exceed the specified values. The test applies to all FDD UE of Release 7 and later releases that support HSDPA, E-DCH with 2 ms TTI and optional Type 1 enhanced performance requirements. Upon the UE transmission on E-DPCCH and E-DPDCH, the SS (System Simulator, i.e. Node-B simulator) reacts with E-HICH = ACK. The UE transmits new data or retransmissions on the corresponding E-DPCCH and E-DPDCH. New data is a sign for ACK, received by the UE while retransmission is a sign for NACK or DTX, received by the UE . The later is interpreted as NACK by higher layer and causes retransmission. Fixed Reference Channels (FRC H-Set 1, QPSK version), RADIO BEARER SETUP message as specified in section 3.1 is configured in R&S®CMU200 with exception of RADIO BEARER SETUP message in Table 28. External multi-path fading simulator is configured with VA30 fading signal. Configuration in R&S®CMU200: BS Signal � Packet Switched � HSUPA Test Mode � HSUPA UL RLC SDU Size �5872 Bit BS Signal � HSUPA � TTI Mode � 2 ms BS Signal � HSUPA � RLC PDU Size � 112 UE Signal � HSUPA � Happy Bit Delay Condition � 2 ms UE Signal � HSUPA � RAB H-ARQ Profile � Max. Number of Retransmission � 15 These settings can be configured in R&S®CMU200 by referring to Figure 1(b), 2(b) and 3(b). Table 32 and 33 show the test parameters for E-HICH – serving E-DCH cell, test requirement Type 1 for Missed ACK when hybrid ARQ acknowledgement indicator is transmitted using 3 consecutive slots – serving E-DCH respectively.

Test parameters for E-HICH – Serving E-DCH cell Parameter Unit Missed ACK



E-HICH Ec/Ior dB -31.6 (test 1)

E-HICH signalling pattern - 100% ACK Table 32: Test parameters for E-HICH – Serving E-DCH cell (Table 10.2.1.2A.5.1 of TS 34.121 [1])




Test requirement Type 1 for Missed ACK when hybrid ARQ acknowledgement indicator is transmitted using 3 consecutive slots – Serving E-DCH cell



1 VA30 -31.6 0.6 0.01 Table 33: Test requirement Type 1 for Missed ACK when hybrid ARQ acknowledgement indicator is transmitted using 3 consecutive slots – Serving E-DCH cell (Table 10.2.1.2A.5.2 of TS 34.121 [1])

Downlink physical channels in section 3.1, Table 32 and Table 33 are configured in R&S®CMU200. The Absolute Grant is set to 4. The Relative Grant is not configured. The expected UL data rate is 237 kbps corresponding to E-TFC Index 39. Configuration in R&S®CMU200: BS Signal � Node-B Settings � Output Channel Power (Ior) � -59.4 dBm BS Signal � Node-B Settings � AWGN Noise Pwr. (@3.84 MHz, Ioc) � Off BS Signal � HSUPA � E-AGCH � AG Pattern � AG Index � 4BS Signal � HSUPA � E-RGCH/E-HICH � HARQ Feedback (E-HICH) � Mode �All ACK BS Signal � Downlink Physical Channels � E-RGCH/E-HICH � E-RGCH/E-HICH �-31.6 dB BS Signal � Downlink Physical Channels � E-RGCH/E-HICH � E-RGCH Active �Off These settings can be configured in R&S®CMU200 by referring to Figure 3(b), 5(a) and 5(e). A HSUPA call is established. Fading simulator is switched on. For Missed ACK, the SS responds with 100% ACK. If UE indicates on the E-DPCCH a retransmission, the ACK from the SS was received as NACK or DTX by the UE and is counted as missed ACK. If the UE indicates on the E-DPCCH new data, the ACK from the SS was received as ACK by the UE and is counted as correct ACK. If the number of retransmission reaches the maximum number of retransmission due to several false or missed ACK detections in series, the first new data on the E-DPDCH with E-DPCCH are not the consequence of ACK and this case is not counted as sample. Configuration in R&S®CMU200: BS Signal � HSUPA � E-RGCH/E-HICH � HARQ Feedback (E-HICH) � Mode �All ACK This setting can be configured in R&S®CMU200 by referring to Figure 17. The test is continued until statistical significance as specified in Table F.6.4 of TS 34.121 [1] is achieved. Measurement result for detection of E-DCH HARQ Indicator Channel (E-HICH) is available in HSUPA E-HICH in R&S®CMU200. Configuration in R&S®CMU200: Menus � Receiver Quality � Applic. 2 � HSUPA E-HICH Figure 18 shows the detection of E-DCH HARQ Indicator Channel (E-HICH) measurement result.





For Missed ACK, recall EHICH2.sav, modify the following configuration and establish CS call. BS Signal � Downlink Physical Channels � E-RGCH/E-HICH � E-RGCH/E-HICH � -31.6 dB

E-DCH category 6

For Missed ACK, recall EHICH2.sav, modify the following configuration and establish PS call. UE Signal � HSUPA � Maximum Channelisation Code � 2xSF2 and 2xSF4 BS Signal � Downlink Physical Channels � E-RGCH/E-HICH � E-RGCH/E-HICH � -31.6 dB



Detection of E-DCH Relative Grant Channel (E-RGCH): Single Link Performance (10 ms TTI) (10.3.1.1)


3.6 Detection of E-DCH Relative Grant Channel (E-RGCH): Single Link Performance (10 ms TTI) (10.3.1.1)

The receive characteristics of the E-DCH Relative Grant Channel (E-RGCH) in multi-path fading environments are determined by the Missed UP/DOWN and Missed HOLD values. The test will verify the average probability for Missed UP/DOWN and Missed HOLD, when E-RGCH is transmitted using 12 consecutive slots, do not exceed the specified values. The test applies to all FDD UE of Release 6 and later releases that support HSDPA and E-DCH. The UE transmits E-DPCCH and E-DPDCH. The SS (System Simulator, i.e. Node-B simulator) transmits E-RGCH UP, DOWN or HOLD (DTX). The UE changes or holds the transport format of the corresponding E-DPCCH and E-DPDCH accordingly. This is visible for the SS by reading the E-TFCI, signalled on the corresponding E-DPCCH. The fail cases for UP are DOWN (erroneous detection) and HOLD (missed detection). The fail cases for DOWN are UP and HOLD. Fixed Reference Channels (FRC H-Set 1, QPSK version), RADIO BEARER SETUP message as specified in section 3.1 is configured in R&S®CMU200 with exception of RADIO BEARER SETUP message in Table 34. External multi-path fading simulator is configured with VA30 fading signal.

Test parameters for E-HICH – Serving E-DCH cell Information Element Value/remark Version

RLC PDU size 112 Rel-6


E-DCH MAC-d flow maximum number of retransmissions 0

E-DCH info Rel-6


- E-DCH minimum set E-TFCI Not Present in RGCH performance tests, all E-TFCs should be in the selection process)

Downlink information for each radio link list

- Downlink information for each radio link

- CHOICE E-RGCH Information Rel-6

- E-RGCH Information

- Signature Sequence 0

- RG combination index 0 Table 34: RADIO BEARER SETUP: Specific Message Contents (Section 10.3.1.1.4.2 and section 10.3.1.1A.4.2 of TS 34.121 [1])

Configuration in R&S®CMU200: BS Signal � HSUPA � TTI Mode � 10 ms BS Signal � HSUPA � RLC PDU Size � 112 BS Signal � HSUPA � E-RGCH/E-HICH � Relative Grant (E-RGCH) � Signature �0UE Signal � HSUPA � Happy Bit Delay Condition � 10 ms UE Signal � HSUPA � Minimum set E-TFCI � OFF UE Signal � HSUPA � RAB H-ARQ Profile � Max. Number of Retransmission � 0




These settings can be configured in R&S®CMU200 by referring to Figure 2(b), 3(b) and as shown in Figure 19.

Figure 19: E-RGCH signature configuration Table 35, 36 and 37 show the test parameters for E-RGCH – serving E-DCH cell, test requirement for Missed UP/DOWN when relative scheduling grant is transmitted using 12 consecutive slots – Serving E-DCH cell and test requirement for Missed HOLD when relative scheduling grant is transmitted using 12 consecutive slots – Serving E-DCH cell respectively.

Test parameters for E-RGCH – Serving E-DCH cell Parameter Unit Missed UP/DOWN Missed HOLD



E-RGCH Ec/Ior dB -30.9 (test 1) -∞ (test 2)

E-RGCH signalling pattern - 50% UP 50% DOWN 100% HOLD

Table 35: Test parameters for E-RGCH – Serving E-DCH cell (Table 10.3.1.1.5.1 of TS 34.121 [1])




Test requirement for Missed UP/DOWN when relative scheduling grant is transmitted using 12 consecutive slots – Serving E-DCH cell


Conditions E-RGCH Ec/Ior (dB) Ior/Ioc (dB) Missed UP/DOWN probability

1 VA30 -30.9 0.6 0.05/0.05 Table 36: Test requirement for Missed UP/DOWN when relative scheduling grant is transmitted using 12 consecutive slots – Serving E-DCH cell (Table 10.3.1.1.5.2 of TS 34.121 [1])

Test requirement for Missed HOLD when relative scheduling grant is transmitted using 12 consecutive slots – Serving E-DCH cell


Conditions Ior/Ioc (dB) Missed HOLD probability

2 VA30 0.6 0.1 Table 37: Test requirement for Missed HOLD when relative scheduling grant is transmitted using 12 consecutive slots – Serving E-DCH cell (Table 10.3.1.1.5.3 of TS 34.121 [1])

Downlink physical channels in section 3.1, Table 35, Table 36 and Table 37 are configured in R&S®CMU200. The Absolute Grant is set to 5. The expected UL data rate is 71.6 kbps corresponding to E-TFC Index 45. Configuration in R&S®CMU200: BS Signal � Node-B Settings � Output Channel Power (Ior) � -59.4 dBm BS Signal � Node-B Settings � AWGN Noise Pwr. (@3.84 MHz, Ioc) � Off BS Signal � HSUPA � E-AGCH � AG Pattern � AG Index � 5BS Signal � Downlink Physical Channels � E-RGCH/E-HICH � E-RGCH/E-HICH �-30.9 dB BS Signal � Downlink Physical Channels � E-RGCH/E-HICH � E-RGCH Active �On These settings can be configured in R&S®CMU200 by referring to Figure 3(b), 5(a) and 5(e). A HSUPA call is established. Fading simulator is switched on. Upon reception of every E-DPCCH and E-DPDCH, “DTX” is always signalled by the SS on the E-HICH during the entire test. This is to ensure no E-HICH power but UE will transmit new data, since “E-DCH MAC-d flow maximum number of retransmissions” is set to 0. Configuration in R&S®CMU200: BS Signal � HSUPA � E-RGCH/E-HICH � HARQ Feedback (E-HICH) � Mode �All DTX This setting can be configured in R&S®CMU200 by referring to Figure 17. Missed UP/DOWN test:4 consecutive “DOWN” is signalled by the SS on the E-RGCH. E-TFCI for 4 consecutive HARQ processes, signalled on the E-DPCCH and corresponding to these “DOWN”, is read by SS. It is counted as Missed DOWN if the UE increases or holds the transport format at each HARQ process upon a “DOWN” command. The UE may transmit less data than granted if Happy Bit = 1 is signalled by the UE. The corresponding E-DPCCH and E-DPDCH TTI is not counted as sample.




4 consecutive “UP” is signalled by the SS on the E-RGCH. E-TFCI for 4 consecutive HARQ processes, signalled on the E-DPCCH and corresponding to these “UP”, is read by SS. It is counted as Missed UP if the UE decreases or holds the transport format at each HARQ process upon a “UP” command. The UE may transmit less data than granted if Happy Bit = 1 is signalled by the UE. The corresponding E-DPCCH and E-DPDCH TTI is not counted as sample. Configuration in R&S®CMU200: BS Signal � HSUPA � E-RGCH/E-HICH � Relative Grant (E-RGCH)� Mode �Alternating H-ARQ Cylce This setting can be configured in R&S®CMU200 by referring to Figure 19. The “DOWN-UP” cycle above is continued until statistical significance as specified in Table F.6.4 of TS 34.121 [1] is achieved for DOWN and UP separately. If one counter reaches the pass criterion, this counter is stopped and the remaining counter is continued. If the last counter reaches pass, the Missed UP DOWN test is pass. If the first counter reaches fail, the Missed UP DOWN test is fail. Due to Missed UP or Missed DOWN the operating range will shift down or up. If the operating range shifts outside the range shown in Table 38, the operating range must be re-adjusted. R&S®CMU200 will re-adjust the operating point when the operating is shifted outside of the operating range.

E-TFCI operating point/range (10 ms) Missed UP

DOWN Missed HOLD AG Value βed/βc E-TFCI TB Size = N*112 + Header + Padding UL rate (kbps)

6 24/15 59 1264 = 11*112 + 18 + 14 126.4

21/15 52 951 = 8* 112 + 18 + 37 95.1 Initial operating point 5 19/15 45 716 = 6*112 + 18 + 26 71.6 Initial

operaing range 17/15 40 584 = 5*112 + 18 + 6 58.4

4 15/15 35 477 = 4*112 + 18 + 11 47.7

13/15 28 359 = 3*112 + 18 + 4 35.9

12/15 19 249 = 2*112 + 18 + 7 24.9 Table 38: E-TFCI operating point/range (10 ms) (Table 10.3.1.1.4.2.1 of TS 34.121 [1]) Configuration in R&S®CMU200: HSUPA E-RGCH � Control � HSUPA E-RGCH � Nr. Of Expected E-TFCI’s � 7HSUPA E-RGCH � Control � HSUPA E-RGCH � Initial E-TFCI Index � 5HSUPA E-RGCH � Control � HSUPA E-RGCH � E-TFCI Value Selection � Auto




Figure 20: E-TFCI configuration The test is continued until statistical significance as specified in Table F.6.4 of TS 34.121 [1] is achieved. Missed HOLD test:“DTX” is signalled by the SS on the E-RGCH. E-TFCI, signalled on the E-DPCCH and corresponding to the “DTX”, is read by SS. It is counted as Missed HOLD if the UE increases or decreases the transport format upon a “DTX” command. The UE may transmit less data than granted if Happy Bit = 1 is signalled by the UE. The corresponding E-DPCCH and E-DPDCH TTI is not counted as sample. Configuration in R&S®CMU200: BS Signal � HSUPA � E-RGCH/E-HICH � Relative Grant (E-RGCH)� Mode � All DTX This setting can be configured in R&S®CMU200 by referring to Figure 19. Missed HOLD test is continued until statistical significance as specified in Table F.6.4 of TS 34.121 [1] is achieved. Due to Missed HOLD the operating range will shift down or up. If the operating range shifts outside the range shown in Table 38, the operating range must be re-adjusted. The test is continued until statistical significance as specified in Table F.6.4 of TS 34.121 [1] is achieved. Measurement result for detection of E-DCH Relative Grant Channel (E-RGCH) is available in HSUPA E-RGCH in R&S®CMU200.




Configuration in R&S®CMU200: Menus � Receiver Quality � Applic. 2 � HSUPA E-RGCH Figure 21(a) and 21(b) show the detection of E-DCH HARQ Indicator Channel (E-HICH) Missed UP/DOWN and Missed HOLD measurement result respectively.

Figure 21(a): E-RGCH Missed UP/DOWN measurement result




Figure 21(b): E-RGCH Missed HOLD measurement result


For Missed UP/DOWN, recall ERGCH10.sav and establish CS call. For Missed HOLD, recall ERGCH10.sav, modify the following configuration and establish CS call. BS Signal � HSUPA � E-RGCH/E-HICH � Relative Grant (E-RGCH)� Mode �All DTX E-DCH category 6

For Missed UP/DOWN, recall ERGCH10.sav, modify the following configuration and establish PS call. UE Signal � HSUPA � Maximum Channelisation Code � 2xSF2 and 2xSF4 For Missed HOLD, recall ERGCH10.sav, modify the following configurations and establish PS call. UE Signal � HSUPA � Maximum Channelisation Code � 2xSF2 and 2xSF4 BS Signal � HSUPA � E-RGCH/E-HICH � Relative Grant (E-RGCH)� Mode �All DTX

The measurement result is available at: Menus � Receiver Quality � Applic. 2 � HSUPA E-RGCH


Detection of E-DCH Relative Grant Channel (E-RGCH): Single Link Performance (10 ms TTI, Type 1) (10.3.1.1A)


3.7 Detection of E-DCH Relative Grant Channel (E-RGCH): Single Link Performance (10 ms TTI, Type 1) (10.3.1.1A)

The receive characteristics of the E-DCH Relative Grant Channel (E-RGCH) in multi-path fading environments are determined by the Missed UP/DOWN. The test will verify the average probability for Missed UP/DOWN, when E-RGCH is transmitted using 12 consecutive slots, do not exceed the specified values. The test applies to all FDD UE of Release 7 and later releases that support HSDPA, E-DCH and the optional Type 1 enhanced performance. The UE transmits E-DPCCH and E-DPDCH. The SS (System Simulator, i.e. Node-B simulator) transmits E-RGCH UP or DOWN. The UE changes or holds the transport format of the corresponding E-DPCCH and E-DPDCH accordingly. This is visible for the SS by reading the E-TFCI, signalled on the corresponding E-DPCCH. The fail cases for UP are DOWN (erroneous detection) and HOLD (missed detection). The fail cases for DOWN are UP and HOLD. Fixed Reference Channels (FRC H-Set 1, QPSK version), RADIO BEARER SETUP message as specified in section 3.1 is configured in R&S®CMU200 with exception of RADIO BEARER SETUP message in Table 34. External multi-path fading simulator is configured with VA30 fading signal. Configuration in R&S®CMU200: BS Signal � HSUPA � TTI Mode � 10 ms BS Signal � HSUPA � RLC PDU Size � 112 BS Signal � HSUPA � E-RGCH/E-HICH � Relative Grant (E-RGCH) � Signature �0UE Signal � HSUPA � Happy Bit Delay Condition � 10 ms UE Signal � HSUPA � Minimum set E-TFCI � OFF UE Signal � HSUPA � RAB H-ARQ Profile � Max. Number of Retransmission � 0

These settings can be configured in R&S®CMU200 by referring to Figure 2(b), 3(b) and as shown in Figure 19. Table 39 and 40 show the test parameters for E-RGCH – serving E-DCH cell and test requirement Type 1 for Missed UP/DOWN when relative scheduling grant is transmitted using 12 consecutive slots – Serving E-DCH respectively.

Test parameters for E-RGCH – Serving E-DCH cell Parameter Unit Missed UP/DOWN



E-RGCH Ec/Ior dB -34.9 (test 1)

E-RGCH signalling pattern - 50% UP 50% DOWN

Table 39: Test parameters for E-RGCH – Serving E-DCH cell (Table 10.3.1.1A.5.1 of TS 34.121 [1])




Test requirement Type 1 for Missed UP/DOWN when relative scheduling grant is transmitted using 12 consecutive slots – Serving E-DCH cell



1 VA30 -34.9 0.6 0.05/0.05 Table 40: Test requirementType 1 for Missed UP/DOWN when relative scheduling grant is transmitted using 12 consecutive slots – Serving E-DCH cell (Table 10.3.1.1A.5.2 of TS 34.121 [1])

Downlink physical channels in section 3.1, Table 39 and Table 40 are configured in R&S®CMU200. The Absolute Grant is set to 5. The expected UL data rate is 71.6 kbps corresponding to E-TFC Index 45. Configuration in R&S®CMU200: BS Signal � Node-B Settings � Output Channel Power (Ior) � -59.4 dBm BS Signal � Node-B Settings � AWGN Noise Pwr. (@3.84 MHz, Ioc) � Off BS Signal � HSUPA � E-AGCH � AG Pattern � AG Index � 5BS Signal � Downlink Physical Channels � E-RGCH/E-HICH � E-RGCH/E-HICH �-34.9 dB BS Signal � Downlink Physical Channels � E-RGCH/E-HICH � E-RGCH Active �On These settings can be configured in R&S®CMU200 by referring to Figure 3(b), 5(a) and 5(e). A HSUPA call is established. Fading simulator is switched on. Upon reception of every E-DPCCH and E-DPDCH, “DTX” is always signalled by the SS on the E-HICH during the entire test. This is to ensure no E-HICH power but UE will transmit new data, since “E-DCH MAC-d flow maximum number of retransmissions” is set to 0. Configuration in R&S®CMU200: BS Signal � HSUPA � E-RGCH/E-HICH � HARQ Feedback (E-HICH) � Mode �All DTX This setting can be configured in R&S®CMU200 by referring to Figure 17. 4 consecutive “DOWN” is signalled by the SS on the E-RGCH. E-TFCI for 4 consecutive HARQ processes, signalled on the E-DPCCH and corresponding to these “DOWN”, is read by SS. It is counted as Missed DOWN if the UE increases or holds the transport format at each HARQ process upon a “DOWN” command. The UE may transmit less data than granted if Happy Bit = 1 is signalled by the UE. The corresponding E-DPCCH and E-DPDCH TTI is not counted as sample. 4 consecutive “UP” is signalled by the SS on the E-RGCH. E-TFCI for 4 consecutive HARQ processes, signalled on the E-DPCCH and corresponding to these “UP”, is read by SS. It is counted as Missed UP if the UE decreases or holds the transport format at each HARQ process upon a “UP” command. The UE may transmit less data than granted if Happy Bit = 1 is signalled by the UE. The corresponding E-DPCCH and E-DPDCH TTI is not counted as sample.




Configuration in R&S®CMU200: BS Signal � HSUPA � E-RGCH/E-HICH � Relative Grant (E-RGCH)� Mode �Alternating H-ARQ Cylce This setting can be configured in R&S®CMU200 by referring to Figure 19. The “DOWN-UP” cycle above is continued until statistical significance as specified in Table F.6.4 of TS 34.121 [1] is achieved for DOWN and UP separately. If one counter reaches the pass criterion, this counter is stopped and the remaining counter is continued. If the last counter reaches pass, the Missed UP DOWN test is pass. If the first counter reaches fail, the Missed UP DOWN test is fail. Due to Missed UP or Missed DOWN the operating range will shift down or up. If the operating range shifts outside the range shown in Table 41, the operating range must be re-adjusted. R&S®CMU200 will re-adjust the operating point when the operating is shifted outside of the operating range.

E-TFCI operating point/range (10 ms) Missed UP DOWN AG Value βed/βc E-TFCI TB Size = N*112 + Header + Padding UL rate (kbps)

6 24/15 59 1264 = 11*112 + 18 + 14 126.4

21/15 52 951 = 8* 112 + 18 + 37 95.1

5 19/15 45 716 = 6*112 + 18 + 26 71.6 Initial operaing range

17/15 40 584 = 5*112 + 18 + 6 58.4

4 15/15 35 477 = 4*112 + 18 + 11 47.7

13/15 28 359 = 3*112 + 18 + 4 35.9

12/15 19 249 = 2*112 + 18 + 7 24.9 Table 41: E-TFCI operating point/range (10 ms) (Table 10.3.1.1A.4.2.1 of TS 34.121 [1]) Configuration in R&S®CMU200: HSUPA E-RGCH � Control � HSUPA E-RGCH � Nr. Of Expected E-TFCI’s � 7HSUPA E-RGCH � Control � HSUPA E-RGCH � Initial E-TFCI Index � 5HSUPA E-RGCH � Control � HSUPA E-RGCH � E-TFCI Value Selection � Auto These settings can be configured in R&S®CMU200 as shown in Figure 20. The test is continued until statistical significance as specified in Table F.6.4 of TS 34.121 [1] is achieved. Measurement result for detection of E-DCH Relative Grant Channel (E-RGCH) is available in HSUPA E-RGCH in R&S®CMU200. Configuration in R&S®CMU200: Menus � Receiver Quality � Applic. 2 � HSUPA E-RGCH Figure 21(a) shows the detection of E-DCH HARQ Indicator Channel (E-HICH) Missed UP/DOWN measurement result.





For Missed UP/DOWN, recall ERGCH10.sav, modify the following configuration and establish CS call. BS Signal � Downlink Physical Channels � E-RGCH/E-HICH � E-RGCH/E-HICH � -34.9 dB E-DCH category 6

For Missed UP/DOWN, recall ERGCH10.sav, modify the following configurations and establish PS call. UE Signal � HSUPA � Maximum Channelisation Code � 2xSF2 and 2xSF4 BS Signal � Downlink Physical Channels � E-RGCH/E-HICH � E-RGCH/E-HICH � -34.9 dB





3.8 Detection of E-DCH Relative Grant Channel (E-RGCH): Single Link Performance (2 ms TTI) (10.3.1.2)

The receive characteristics of the E-DCH Relative Grant Channel (E-RGCH) in multi-path fading environments are determined by the Missed UP/DOWN and Missed HOLD values. The test will verify the average probability for Missed UP/DOWN and Missed HOLD, when E-RGCH is transmitted using 3 consecutive slots, do not exceed the specified values. The test applies to all FDD UE of Release 6 and later releases that support HSDPA and E-DCH with 2 ms TTI. The UE transmits E-DPCCH and E-DPDCH. The SS (System Simulator, i.e. Node-B simulator) transmits E-RGCH UP, DOWN or HOLD (DTX). The UE changes or holds the transport format of the corresponding E-DPCCH and E-DPDCH accordingly. This is visible for the SS by reading the E-TFCI, signalled on the corresponding E-DPCCH. The fail cases for UP are DOWN (erroneous detection) and HOLD (missed detection). The fail cases for DOWN are UP and HOLD. Fixed Reference Channels (FRC H-Set 1, QPSK version), RADIO BEARER SETUP message as specified in section 3.1 is configured in R&S®CMU200 with exception of RADIO BEARER SETUP message in Table 42. External multi-path fading simulator is configured with VA30 fading signal.

Test parameters for E-HICH – Serving E-DCH cell Information Element Value/remark Version

RLC PDU size 112 Rel-6

- E-DCH Transmission Time 10 ms (Test 2 and 4), 2 ms (Test 1 and 3)


E-DCH info Rel-6

- Happy bit delay condition 10 ms (Test 2 and 4), 2 ms (Test 1 and 3) (indication of exhausted resources on frame basis)

- E-DCH minimum set E-TFCI Not Present in RGCH performance tests, all E-TFCs should be in the selection process)

Downlink information for each radio link list

- Downlink information for each radio link

- CHOICE E-RGCH Information Rel-6

- E-RGCH Information

- Signature Sequence 0

- RG combination index 0 Table 42: RADIO BEARER SETUP: Specific Message Contents (Section 10.3.1.2.4.2 and section 10.3.1.2A.4.2 of TS 34.121 [1])




Configuration in R&S®CMU200: BS Signal � Packet Switched � HSUPA Test Mode � HSUPA UL RLC SDU Size �5872 Bit BS Signal � HSUPA � TTI Mode � 2 ms BS Signal � HSUPA � RLC PDU Size � 112 BS Signal � HSUPA � E-RGCH/E-HICH � Relative Grant (E-RGCH) � Signature �0UE Signal � HSUPA � Happy Bit Delay Condition � 2 ms UE Signal � HSUPA � Minimum set E-TFCI � OFF UE Signal � HSUPA � RAB H-ARQ Profile � Max. Number of Retransmission � 0

These settings can be configured in R&S®CMU200 by referring to Figure 2(b), 3(b) and as shown in Figure 19. Table 43, 44 and 45 show the test parameters for E-RGCH – serving E-DCH cell, test requirement for Missed UP/DOWN when relative scheduling grant is transmitted using 3 consecutive slots – Serving E-DCH cell and test requirement for Missed HOLD when relative scheduling grant is transmitted using 3 consecutive slots – Serving E-DCH cell respectively.

Test parameters for E-RGCH – Serving E-DCH cell Parameter Unit Missed UP/DOWN Missed HOLD



E-RGCH Ec/Ior dB -24.3 (test 1) -∞ (test 2)

E-RGCH signalling pattern - 50% UP 50% DOWN 100% HOLD

Table 43: Test parameters for E-RGCH – Serving E-DCH cell (Table 10.3.1.2.5.1 of TS 34.121 [1])

Test requirement for Missed UP/DOWN when relative scheduling grant is transmitted using 3 consecutive slots – Serving E-DCH cell



1 VA30 -24.3 0.6 0.05/0.05 Table 44: Test requirement for Missed UP/DOWN when relative scheduling grant is transmitted using 3 consecutive slots – Serving E-DCH cell (Table 10.3.1.2.5.2 of TS 34.121 [1])

Test requirement for Missed HOLD when relative scheduling grant is transmitted using 3 consecutive slots – Serving E-DCH cell


Conditions Ior/Ioc (dB) Missed HOLD probability

2 VA30 0.6 0.1 Table 45: Test requirement for Missed HOLD when relative scheduling grant is transmitted using 3 consecutive slots – Serving E-DCH cell (Table 10.3.1.2.5.3 of TS 34.121 [1])

Downlink physical channels in section 3.1, Table 43, Table 44 and Table 45 are configured in R&S®CMU200. The Absolute Grant is set to 4. The expected UL data rate is 237 kbps corresponding to E-TFC Index 39.




Configuration in R&S®CMU200: BS Signal � Node-B Settings � Output Channel Power (Ior) � -59.4 dBm BS Signal � Node-B Settings � AWGN Noise Pwr. (@3.84 MHz, Ioc) � Off BS Signal � HSUPA � E-AGCH � AG Pattern � AG Index � 4BS Signal � Downlink Physical Channels � E-RGCH/E-HICH � E-RGCH/E-HICH �-24.3 dB BS Signal � Downlink Physical Channels � E-RGCH/E-HICH � E-RGCH Active �On

These settings can be configured in R&S®CMU200 by referring to Figure 3(b), 5(a) and 5(e). A HSUPA call is established. Fading simulator is switched on. Upon reception of every E-DPCCH and E-DPDCH, “DTX” is always signalled by the SS on the E-HICH during the entire test. This is to ensure no E-HICH power but UE will transmit new data, since “E-DCH MAC-d flow maximum number of retransmissions” is set to 0. Configuration in R&S®CMU200: BS Signal � HSUPA � E-RGCH/E-HICH � HARQ Feedback (E-HICH) � Mode �All DTX This setting can be configured in R&S®CMU200 by referring to Figure 17. Missed UP/DOWN test:8 consecutive “UP” is signalled by the SS on the E-RGCH. E-TFCI for 8 consecutive HARQ processes, signalled on the E-DPCCH and corresponding to these “UP”, is read by SS. It is counted as Missed UP if the UE decreases or holds the transport format at each HARQ process upon a “UP” command. The UE may transmit less data than granted if Happy Bit = 1 is signalled by the UE. The corresponding E-DPCCH and E-DPDCH TTI is not counted as sample. 8 consecutive “DOWN” is signalled by the SS on the E-RGCH. E-TFCI for 8 consecutive HARQ processes, signalled on the E-DPCCH and corresponding to these “DOWN”, is read by SS. It is counted as Missed DOWN if the UE increases or holds the transport format at each HARQ process upon a “DOWN” command. The UE may transmit less data than granted if Happy Bit = 1 is signalled by the UE. The corresponding E-DPCCH and E-DPDCH TTI is not counted as sample. Configuration in R&S®CMU200: BS Signal � HSUPA � E-RGCH/E-HICH � Relative Grant (E-RGCH)� Mode �Alternating H-ARQ Cylce This setting can be configured in R&S®CMU200 by referring to Figure 19. The “UP-DOWN” cycle above is continued until statistical significance as specified in Table F.6.4 of TS 34.121 [1] is achieved for UP and DOWN separately. If one counter reaches the pass criterion, this counter is stopped and the remaining counter is continued. If the last counter reaches pass, the Missed UP DOWN test is pass. If the first counter reaches fail, the Missed UP DOWN test is fail. Due to Missed UP or Missed DOWN the operating range will shift down or up. If the operating point shifts into the range “risk of buffer underflow” or “ambiguous E-TFCI” in




Table 46, the operating point must be re-adjusted. R&S®CMU200 will re-adjust the operating point when the operating is shifted outside of the operating range.

E-TFCI operating point/range (2 ms) Missed UP

DOWN Missed HOLD AG Value βed/βc E-TFCI TB Size = N*112 + Header + min

Padding UL rate (kbps)

Risk of buffer underflow

21/15 54 817 = 7*112 + 18 + 15 408

5 19/15 50 707 = 6*112 + 18 + 17 353.5

17/15 45 590 = 5*112 + 18 + 12 295.5 Initial operaing range

Initial operating point 4 15/15 39 474 = 4*112 + 18 + 8 273

13/15 31 355 = 3*112 + 18 + 1 177.5

12/15 21 247 = 2*112 + 18 + 5 123.5 Ambiguous E-TFCI

3 11/15 21 247 = 2*112 + 18 + 5 123.5 Table 46: E-TFCI operating point/range (2 ms) (Table 10.3.1.2.4.2.1 of TS 34.121 [1]) Configuration in R&S®CMU200: HSUPA E-RGCH � Control � HSUPA E-RGCH � Nr. Of Expected E-TFCI’s � 6HSUPA E-RGCH � Control � HSUPA E-RGCH � Initial E-TFCI Index � 3HSUPA E-RGCH � Control � HSUPA E-RGCH � E-TFCI Value Selection � Auto These settings can be configured in R&S®CMU200 by referring to Figure 20. The test is continued until statistical significance as specified in Table F.6.4 of TS 34.121 [1] is achieved. Missed HOLD test:“DTX” is signalled by the SS on the E-RGCH. E-TFCI, signalled on the E-DPCCH and corresponding to the “DTX”, is read by SS. It is counted as Missed HOLD if the UE increases or decreases the transport format upon a “DTX” command. The UE may transmit less data than granted if Happy Bit = 1 is signalled by the UE. The corresponding E-DPCCH and E-DPDCH TTI is not counted as sample. Configuration in R&S®CMU200: BS Signal � HSUPA � E-RGCH/E-HICH � Relative Grant (E-RGCH)� Mode � All DTX This setting can be configured in R&S®CMU200 by referring to Figure 19. Missed HOLD test is continued until statistical significance as specified in Table F.6.4 of TS 34.121 [1] is achieved. Due to Missed HOLD the operating range will shift down or up. If the operating point shifts into the range “risk of buffer underflow” or “ambiguous E-TFCI” in Table 46, the operating point must be re-adjusted. R&S®CMU200 will re-adjust the operating point when the operating is shifted outside of the operating range. The test is continued until statistical significance as specified in Table F.6.4 of TS 34.121 [1] is achieved. Measurement result for detection of E-DCH Relative Grant Channel (E-RGCH) is available in HSUPA E-RGCH in R&S®CMU200.




Configuration in R&S®CMU200: Menus � Receiver Quality � Applic. 2 � HSUPA E-RGCH Figure 21(a) and 21(b) show the detection of E-DCH HARQ Indicator Channel (E-HICH) Missed UP/DOWN and Missed HOLD measurement result respectively.


For Missed UP/DOWN, recall ERGCH2.sav and establish CS call. For Missed HOLD, recall ERGCH2.sav, modify the following configuration and establish CS call. BS Signal � HSUPA � E-RGCH/E-HICH � Relative Grant (E-RGCH)� Mode �All DTX E-DCH category 6

For Missed UP/DOWN, recall ERGCH2.sav, modify the following configuration and establish PS call. UE Signal � HSUPA � Maximum Channelisation Code � 2xSF2 and 2xSF4 For Missed HOLD, recall ERGCH2.sav, modify the following configurations and establish PS call. UE Signal � HSUPA � Maximum Channelisation Code � 2xSF2 and 2xSF4 BS Signal � HSUPA � E-RGCH/E-HICH � Relative Grant (E-RGCH)� Mode �All DTX





3.9 Detection of E-DCH Relative Grant Channel (E-RGCH): Single Link Performance (2 ms TTI, Type 1) (10.3.1.2A)

The receive characteristics of the E-DCH Relative Grant Channel (E-RGCH) in multi-path fading environments are determined by the Missed UP/DOWN values. The test will verify the average probability for Missed UP/DOWN, when E-RGCH is transmitted using 3 consecutive slots, do not exceed the specified values. The test applies to all FDD UE of Release 7 and later releases that support HSDPA , E-DCH with 2 ms TTI and the optional Type 1 enhanced performance requirements. The UE transmits E-DPCCH and E-DPDCH. The SS (System Simulator, i.e. Node-B simulator) transmits E-RGCH UP or DOWN. The UE changes or holds the transport format of the corresponding E-DPCCH and E-DPDCH accordingly. This is visible for the SS by reading the E-TFCI, signalled on the corresponding E-DPCCH. The fail cases for UP are DOWN (erroneous detection) and HOLD (missed detection). The fail cases for DOWN are UP and HOLD. Fixed Reference Channels (FRC H-Set 1, QPSK version), RADIO BEARER SETUP message as specified in section 3.1 is configured in R&S®CMU200 with exception of RADIO BEARER SETUP message in Table 42. External multi-path fading simulator is configured with VA30 fading signal. Configuration in R&S®CMU200: BS Signal � Packet Switched � HSUPA Test Mode � HSUPA UL RLC SDU Size �5872 Bit BS Signal � HSUPA � TTI Mode � 2 ms BS Signal � HSUPA � RLC PDU Size � 112 BS Signal � HSUPA � E-RGCH/E-HICH � Relative Grant (E-RGCH) � Signature �0UE Signal � HSUPA � Happy Bit Delay Condition � 2 ms UE Signal � HSUPA � Minimum set E-TFCI � OFF UE Signal � HSUPA � RAB H-ARQ Profile � Max. Number of Retransmission � 0

These settings can be configured in R&S®CMU200 by referring to Figure 2(b), 3(b) and as shown in Figure 19. Table 47 and 48 show the test parameters for E-RGCH – serving E-DCH cell and test requirement Type 1 for Missed UP/DOWN when relative scheduling grant is transmitted using 3 consecutive slots – Serving E-DCH cell respectively.

Test parameters for E-RGCH – Serving E-DCH cell Parameter Unit Missed UP/DOWN



E-RGCH Ec/Ior dB -28.4 (test 1)

E-RGCH signalling pattern - 50% UP 50% DOWN

Table 47: Test parameters for E-RGCH – Serving E-DCH cell (Table 10.3.1.2A.5.1 of TS 34.121 [1])




Test requirement Type 1 for Missed UP/DOWN when relative scheduling grant is transmitted using 3 consecutive slots – Serving E-DCH cell



1 VA30 -28.4 0.6 0.05/0.05 Table 48: Test requirement Type 1 for Missed UP/DOWN when relative scheduling grant is transmitted using 3 consecutive slots – Serving E-DCH cell (Table 10.3.1.2A.5.2 of TS 34.121 [1])

Downlink physical channels in section 3.1, Table 47 and Table 48 are configured in R&S®CMU200. The Absolute Grant is set to 4. The expected UL data rate is 237 kbps corresponding to E-TFC Index 39. Configuration in R&S®CMU200: BS Signal � Node-B Settings � Output Channel Power (Ior) � -59.4 dBm BS Signal � Node-B Settings � AWGN Noise Pwr. (@3.84 MHz, Ioc) � Off BS Signal � HSUPA � E-AGCH � AG Pattern � AG Index � 4BS Signal � Downlink Physical Channels � E-RGCH/E-HICH � E-RGCH/E-HICH �-28.4 dB BS Signal � Downlink Physical Channels � E-RGCH/E-HICH � E-RGCH Active �On These settings can be configured in R&S®CMU200 by referring to Figure 3(b), 5(a) and 5(e). A HSUPA call is established. Fading simulator is switched on. Upon reception of every E-DPCCH and E-DPDCH, “DTX” is always signalled by the SS on the E-HICH during the entire test. This is to ensure no E-HICH power but UE will transmit new data, since “E-DCH MAC-d flow maximum number of retransmissions” is set to 0. Configuration in R&S®CMU200: BS Signal � HSUPA � E-RGCH/E-HICH � HARQ Feedback (E-HICH) � Mode �All DTX This setting can be configured in R&S®CMU200 by referring to Figure 17. 8 consecutive “UP” is signalled by the SS on the E-RGCH. E-TFCI for 8 consecutive HARQ processes, signalled on the E-DPCCH and corresponding to these “UP”, is read by SS. It is counted as Missed UP if the UE decreases or holds the transport format at each HARQ process upon a “UP” command. The UE may transmit less data than granted if Happy Bit = 1 is signalled by the UE. The corresponding E-DPCCH and E-DPDCH TTI is not counted as sample. 8 consecutive “DOWN” is signalled by the SS on the E-RGCH. E-TFCI for 8 consecutive HARQ processes, signalled on the E-DPCCH and corresponding to these “DOWN”, is read by SS. It is counted as Missed DOWN if the UE increases or holds the transport format at each HARQ process upon a “DOWN” command. The UE may transmit less data than granted if Happy Bit = 1 is signalled by the UE. The corresponding E-DPCCH and E-DPDCH TTI is not counted as sample.




Configuration in R&S®CMU200: BS Signal � HSUPA � E-RGCH/E-HICH � Relative Grant (E-RGCH)� Mode �Alternating H-ARQ Cylce This setting can be configured in R&S®CMU200 by referring to Figure 19. The “UP-DOWN” cycle above is continued until statistical significance as specified in Table F.6.4 of TS 34.121 [1] is achieved for UP and DOWN separately. If one counter reaches the pass criterion, this counter is stopped and the remaining counter is continued. If the last counter reaches pass, the Missed UP DOWN test is pass. If the first counter reaches fail, the Missed UP DOWN test is fail. Due to Missed UP or Missed DOWN the operating range will shift down or up. If the operating point shifts into the range “risk of buffer underflow” or “ambiguous E-TFCI” in Table 49 the operating point must be re-adjusted. R&S®CMU200 will re-adjust the operating point when the operating is shifted outside of the operating range.

E-TFCI operating point/range (2 ms) Missed UP DOWN AG Value βed/βc E-TFCI TB Size = N*112 + Header + min Padding UL rate (kbps)

Risk of buffer underflow

21/15 54 817 = 7*112 + 18 + 15 408

5 19/15 50 707 = 6*112 + 18 + 17 353.5

17/15 45 590 = 5*112 + 18 + 12 295.5 Initial operating range

4 15/15 39 474 = 4*112 + 18 + 8 273

13/15 31 355 = 3*112 + 18 + 1 177.5

12/15 21 247 = 2*112 + 18 + 5 123.5 Ambiguous E-TFCI

3 11/15 21 247 = 2*112 + 18 + 5 123.5 Table 49: E-TFCI operating point/range (2 ms) (Table 10.3.1.2A.4.2.1 of TS 34.121 [1]) Configuration in R&S®CMU200: HSUPA E-RGCH � Control � HSUPA E-RGCH � Nr. Of Expected E-TFCI’s � 6HSUPA E-RGCH � Control � HSUPA E-RGCH � Initial E-TFCI Index � 3HSUPA E-RGCH � Control � HSUPA E-RGCH � E-TFCI Value Selection � Auto These settings can be configured in R&S®CMU200 by referring to Figure 20. The test is continued until statistical significance as specified in Table F.6.4 of TS 34.121 [1] is achieved. Measurement result for detection of E-DCH Relative Grant Channel (E-RGCH) is available in HSUPA E-RGCH in R&S®CMU200. Configuration in R&S®CMU200: Menus � Receiver Quality � Applic. 2 � HSUPA E-RGCH Figure 21(a) shows the detection of E-DCH HARQ Indicator Channel (E-HICH) Missed UP/DOWN measurement result.





For Missed UP/DOWN, recall ERGCH2.sav, modify the following configuration and establish CS call. BS Signal � Downlink Physical Channels � E-RGCH/E-HICH � E-RGCH/E-HICH � -28.4 dB E-DCH category 6

For Missed UP/DOWN, recall ERGCH2.sav, modify the following configuration and establish PS call. UE Signal � HSUPA � Maximum Channelisation Code � 2xSF2 and 2xSF4 BS Signal � Downlink Physical Channels � E-RGCH/E-HICH � E-RGCH/E-HICH � -28.4 dB



Demodulation of E-DCH Absolute Grant Channel (E-AGCH): Single Link Performance (10.4.1)


3.10 Demodulation of E-DCH Absolute Grant Channel (E-AGCH): Single Link Performance (10.4.1)

The receive characteristics of the E-DCH Absolute Grant Channel (E-AGCH) in multi-path fading environments are determined by the missed detection probability. The test will verify that the missed detection probability of the E-AGCH channel does not exceed 0.01. The test applies to all FDD UE of Release 6 and later releases that support HSDPA and E-DCH. Fixed Reference Channels (FRC H-Set 1, QPSK version), RADIO BEARER SETUP message as specified in section 3.1 is configured in R&S®CMU200 with exception of RADIO BEARER SETUP message in Table 50. External multi-path fading simulator is configured with VA30 fading signal.

Table 50: RADIO BEARER SETUP: Specific Message Contents (Section 10.4.1.4.2 and section 10.4.1A.4.2 of TS 34.121 [1]) Configuration in R&S®CMU200: BS Signal � Packet Switched � HSUPA Test Mode � HSUPA UL RLC SDU Size �8808 Bit BS Signal � HSUPA � TTI Mode � 10 ms UE Signal � HSUPA � RAB H-ARQ Profile � Max. Number of Retransmission � 0

These settings can be configured in R&S®CMU200 by referring to Figure 1(b), 2(b) and 3(b). Table 51, 52 and 53 show the test parameters for E-AGCH detection – single link, test requirement for E-AGCH detection – single link and mapping of the E-AGCH test sequence and the expected E-TFCI respectively. Test parameters for E-AGCH detection – single link

Parameter Unit



P-CPICH Ec_Ior dB -10

E-AGCH information

The E-AGCH information sequence “AG4 AG8 AG10 AG4AG8 AG10 AG4 AG8 AG10,…” shall be transmitted

continuously, where AG4, AG8 and AG10 denote absolute grant index of 4, 8, 10 respectively

E-AGCH TTI length ms 10

E-HICH Ec_Ior dB -20

βc 15/15

βd 5/15

βHS 15/15 Table 51: Test parameters for E-AGCH detection – single link (Table 10.4.1.3 and Table 10.4.1A.3 of TS 34.121 [1])






Test requirement for E-AGCH detection – single link Reference Value

Test Number Propagation Conditions E-AGCH Ec/Ior (dB) Ior/Ioc (dB) Missed detection probability

1 VA30 -23.1 0.6 0.01 Table 52: Test requirement for E-AGCH detection – single link (Table 10.4.1.3a of TS 34.121 [1])

Downlink physical channels in section 3.1, Table 51 and Table 52 are configured in R&S®CMU200. The Relative Grant is not configured. Configuration in R&S®CMU200: BS Signal � Node-B Settings � Output Channel Power (Ior) � -59.4 dBm BS Signal � Node-B Settings � AWGN Noise Pwr. (@3.84 MHz, Ioc) � Off BS Signal � HSUPA � E-AGCH � AG Pattern � Pattern Length � 3BS Signal � HSUPA � E-AGCH � AG Pattern � AG Index � 4 8 10 BS Signal � Downlink Physical Channels � P-CPICH � -10.0 dB BS Signal � Downlink Physical Channels � E-RGCH/E-HICH � E-RGCH/E-HICH �-20.0 dB UE Signal � UE Gain Factors � Packet Data � HSDPA / HSUPA � βc � 15 UE Signal � UE Gain Factors � Packet Data � HSDPA / HSUPA � βd � 5UE Signal � UE Gain Factors � Packet Data � HSDPA / HSUPA � ∆ACK � 5UE Signal � UE Gain Factors � Packet Data � HSDPA / HSUPA � ∆NACK � 5UE Signal � UE Gain Factors � Packet Data � HSDPA / HSUPA � ∆CQI � 5BS Signal � Downlink Physical Channels � E-RGCH/E-HICH � E-RGCH/E-HICH �-23.1 dB BS Signal � Downlink Physical Channels � E-RGCH/E-HICH � E-RGCH Active �Off These settings can be configured in R&S®CMU200 by referring to Figure 3(a), 5(b), 5(e) and 11. A HSUPA call is established. Fading simulator is switched on. 100% ACK is signalled by the SS on the E-HICH for all processes. Absolute Grants according to the E-AGCH information sequence as defined in Table 51 is signalled by the SS. The E-TFCI transmitted on the E-DPCCH for each E-DCH TTI is analyzed by the SS to determine if a missed detection event has occurred by correlating the detected E-TFCIs with the expected E-TFCIs corresponding to the abosolute grant sequence sent on E-AGCH. A missed detection event is recorded if the expected E-TFC is not detected by the SS. Configuration in R&S®CMU200: BS Signal � HSUPA � E-RGCH/E-HICH � HARQ Feedback (E-HICH) � Mode �All ACK This setting can be configured in R&S®CMU200 by referring to Figure 17. The exact mapping of the E-AGCH absolute grant indices and the expected E-TFCIs are shown in Table 53. The mapping shall be used by the SS to compute the missed detection probability.




Mapping of the E-AGCH test sequence and the expected E-TFCI Absolute Grant Index Expected E-TFCI Index

AG4 E-TFCI28

AG8 E-TFCI67

AG10 E-TFCI81 Note: E-TFCI28, E-TFCI67 and E-TFCI81 denote the E-TFC index of 28, 67 and 81 from 10ms TTI Table 0 in TS 25.321 [5]. This mapping is based on the assumption that 1, 5 or 9 RLC PDUs of size 336 bits are used respectively. Table 53: Mapping of the E-AGCH test sequence and the expected E-TFCI (Table 10.4.1.4 and Table 10.4.1A.4 of TS 34.121 [1])

The test is continued until statistical significance as specified in Table F.6.4 of TS 34.121 [1] is achieved. Measurement result for demodulation of E-DCH Absolute Grant Channel (E-AGCH) is available in HSUPA E-AGCH in R&S®CMU200. Configuration in R&S®CMU200: Menus � Receiver Quality � Applic. 2 � HSUPA E-AGCH HSUPA E-AGCH � Measure Type � Missed Detection Figure 22 shows the E-AGCH missed detection measurement result.

Figure 22: E-AGCH missed detection measurement result





Recall EAGCH.sav and establish CS call.

E-DCH category 6

Recall EAGCH.sav, modify the following configuration and establish PS call. UE Signal � HSUPA � Maximum Channelisation Code � 2xSF2 and 2xSF4

The measurement result is available at: Menus � Receiver Quality � Applic. 2 � HSUPA E-AGCH HSUPA E-AGCH � Measure Type � Missed Detection


Demodulation of E-DCH Absolute Grant Channel (E-AGCH): Single Link Performance (Type 1) (10.4.1A)


3.11 Demodulation of E-DCH Absolute Grant Channel (E-AGCH): Single Link Performance (Type 1) (10.4.1A)

The receive characteristics of the E-DCH Absolute Grant Channel (E-AGCH) in multi-path fading environments are determined by the missed detection probability. The test will verify that the missed detection probability of the E-AGCH channel does not exceed 0.01. The test applies to all FDD UE of Release 7 and later releases that support HSDPA, E-DCH and the optional Type 1 enhanced performance requirements. Fixed Reference Channels (FRC H-Set 1, QPSK version), RADIO BEARER SETUP message as specified in section 3.1 is configured in R&S®CMU200 with exception of RADIO BEARER SETUP message in Table 50. External multi-path fading simulator is configured with VA30 fading signal. Configuration in R&S®CMU200: BS Signal � Packet Switched � HSUPA Test Mode � HSUPA UL RLC SDU Size �8808 Bit BS Signal � HSUPA � TTI Mode � 10 ms UE Signal � HSUPA � RAB H-ARQ Profile � Max. Number of Retransmission � 0

These settings can be configured in R&S®CMU200 by referring to Figure 1(b), 2(b) and 3(b). Table 51 and 54 show the test parameters for E-AGCH detection – single link and test requirement for E-AGCH detection – single link respectively.

Test requirement for E-AGCH detection – single link Reference Value

Test Number Propagation Conditions E-AGCH Ec/Ior (dB) Ior/Ioc (dB) Missed detection probability

1 VA30 -26.7 0.6 0.01 Table 54: Test requirement for E-AGCH detection – single link (Table 10.4.1A.5 of TS 34.121 [1])

Downlink physical channels in section 3.1, Table 51 and Table 54 are configured in R&S®CMU200. The Relative Grant is not configured.




Configuration in R&S®CMU200: BS Signal � Node-B Settings � Output Channel Power (Ior) � -59.4 dBm BS Signal � Node-B Settings � AWGN Noise Pwr. (@3.84 MHz, Ioc) � Off BS Signal � HSUPA � E-AGCH � AG Pattern � Pattern Length � 3BS Signal � HSUPA � E-AGCH � AG Pattern � AG Index � 4 8 10 BS Signal � Downlink Physical Channels � P-CPICH � -10.0 dB BS Signal � Downlink Physical Channels � E-RGCH/E-HICH � E-RGCH/E-HICH �-20.0 dB UE Signal � UE Gain Factors � Packet Data � HSDPA / HSUPA � βc � 15 UE Signal � UE Gain Factors � Packet Data � HSDPA / HSUPA � βd � 5UE Signal � UE Gain Factors � Packet Data � HSDPA / HSUPA � ∆ACK � 5UE Signal � UE Gain Factors � Packet Data � HSDPA / HSUPA � ∆NACK � 5UE Signal � UE Gain Factors � Packet Data � HSDPA / HSUPA � ∆CQI � 5

BS Signal � Downlink Physical Channels � E-RGCH/E-HICH � E-RGCH/E-HICH �-26.7 dB BS Signal � Downlink Physical Channels � E-RGCH/E-HICH � E-RGCH Active �Off These settings can be configured in R&S®CMU200 by referring to Figure 3(a), 5(b), 5(e) and 11. A HSUPA call is established. Fading simulator is switched on. 100% ACK is signalled by the SS on the E-HICH for all processes. Absolute Grants according to the E-AGCH information sequence as defined in Table 51 is signalled by the SS. The E-TFCI transmitted on the E-DPCCH for each E-DCH TTI is analyzed by the SS to determine if a missed detection event has occurred by correlating the detected E-TFCIs with the expected E-TFCIs corresponding to the abosolute grant sequence sent on E-AGCH. A missed detection event is recorded if the expected E-TFC is not detected by the SS. Configuration in R&S®CMU200: BS Signal � HSUPA � E-RGCH/E-HICH � HARQ Feedback (E-HICH) � Mode �All ACK This setting can be configured in R&S®CMU200 by referring to Figure 17. The exact mapping of the E-AGCH absolute grant indices and the expected E-TFCIs are shown in Table 53. The mapping shall be used by the SS to compute the missed detection probability. The test is continued until statistical significance as specified in Table F.6.4 of TS 34.121 [1] is achieved. Measurement result for demodulation of E-DCH Absolute Grant Channel (E-AGCH) is available in HSUPA E-AGCH in R&S®CMU200. Configuration in R&S®CMU200: Menus � Receiver Quality � Applic. 2 � HSUPA E-AGCH HSUPA E-AGCH � Measure Type � Missed Detection




Figure 22 shows the E-AGCH missed detection measurement result.


Recall EAGCH.sav, modify the following configuration and establish CS call. BS Signal � Downlink Physical Channels � E-RGCH/E-HICH � E-RGCH/E-HICH � -26.7 dB E-DCH category 6

Recall EAGCH.sav, modify the following configurations and establish PS call. UE Signal � HSUPA � Maximum Channelisation Code � 2xSF2 and 2xSF4 BS Signal � Downlink Physical Channels � E-RGCH/E-HICH � E-RGCH/E-HICH � -26.7 dB

The measurement result is available at: Menus � Receiver Quality � Applic. 2 � HSUPA E-AGCH HSUPA E-AGCH � Measure Type � Missed Detection

Summary of R&S®CMU200 *.SAV Files



4 Summary of R&S®CMU200 *.SAV Files Table below summarizes the available *.sav files based on R&S®CMU200 firmware V5.03 for UE supporting operating band I and power class 3 in RMC 12.2 kbps + HSPA. Summary of *.SAV files (Firmware V5.03, UE operating band I, power class 3 and E-DCH category 5)

Clause Test parameter *.SAV filename 5.2B Maximum output power with HS-DPCCH and E-DCH 5.2D UE relative code domain power accuracy for HS-DPCCH and E-DCH 5.9B Spectrum emission mask with E-DCH

5.10B Adjacent channel leakage power ratio (ACLR) with E-DCH 5.13.2B Relative code domain error with HS-DPCCH and E-DCH

HSUPATx1.sav HSUPATx2.sav HSUPATx3.sav HSUPATx4.sav HSUPATx5.sav

10.2.1.1 Detection of E-DCH HARQ ACK Indicator Channel (E-HICH): Single Link Performance (10 ms TTI) EHICH10.sav

10.2.1.1A Detection of E-DCH HARQ ACK Indicator Channel (E-HICH): Single Link Performance (10 ms TTI and Type 1) EHICH10.sav

10.2.1.2 Detection of E-DCH HARQ ACK Indicator Channel (E-HICH): Single Link Performance (2 ms TTI) EHICH2.sav

10.2.1.2A Detection of E-DCH HARQ ACK Indicator Channel (E-HICH): Single Link Performance (2 ms TTI and Type 1) EHICH2.sav

10.3.1.1 Detection of E-DCH Relative Grant Channel (E-RGCH): Single Link Performance (10 ms TTI) ERGCH10.sav

10.3.1.1A Detection of E-DCH Relative Grant Channel (E-RGCH): Single Link Performance (10 ms TTI and Type 1) ERGCH10.sav

10.3.1.2 Detection of E-DCH Relative Grant Channel (E-RGCH): Single Link Performance (2 ms TTI) ERGCH2.sav

10.3.1.2A Detection of E-DCH Relative Grant Channel (E-RGCH): Single Link Performance (2 ms TTI and Type 1) ERGCH2.sav

10.4.1 Demodulation of E-DCH Absolute Grant Channel (E-AGCH): Single Link Performance EAGCH.sav

10.4.1A Demodulation of E-DCH Absolute Grant Channel (E-AGCH): Single Link Performance (Type 1) EAGCH.sav

Reference



5 Reference [1] Technical Specification Group Radio Access Network; User Equipment (UE) Conformance Specification; 3GPP TS 34.121-1 V8.7.0, June 2009 [2] Technical Specification Group Radio Access Network; Terminal logical test interface; 3GPP TS 34.109 V8.0.0, December 2008 [3] Technical Specification Group Radio Access Network; Common test environments for User Equipment (UE); 3GPP TS 34.108 V8.7.0, June 2009 [4] Technical Specification Group Radio Access Network; User Equipment (UE) radio transmission and reception (FDD); 3GPP TS 25.101 V8.6.0, March 2009 [5] Technical Specification Group Radio Access Network; Medium Access Control (MAC) protocol specification; 3GPP TS 25.321 V8.6.0, June 2009 [6] Rohde & Schwarz; Application Note: Measurements on 3GPP UE’s according to TS34.121 with CMUgo: Tests with combined Instruments, 1MA130, October 2008 [7] Rohde & Schwarz; Reiner Stuhlfauth; High Speed Uplink Packet Access, HSUPA – RF measurements with CMU200 radio communication tester [8] Rohde & Schwarz; Application Note: Operation Guide for HSUPA Test Set-up According to 3GPP TS 34.121, RCS0712-0053, March 2008

Ordering Information



6 Ordering Information Ordering information Type Description Order no.

R&S®CMU200 Base unit with following accessories: power cord, operating and service manual for instrument

1100.0008.02

R&S®CMU200-B21 Unversal signaling unit; provides multistandard signaling hardware; required for WCDMA 3GPP FDD

1100.5200.14

R&S®CMU200-B56 WCDMA (3GPP FDD) signaling module for CMU-B21 model 14 1150.1850.14

R&S®CMU200-B68

Versatile baseband board for WCDMA (3GPP FDD) layer 1, DL and UL, non-signaling

1149.9809.02

R&S®CMU200-K16

WCDMA (3GPP FDD) band 10, UE test signaling software (R&S®CMU200-B68, R&S®CMU200-B21 model 14 or 54, R&S®CMU200-B56 necessary)

1200.9158.02

R&S®CMU200-K17

WCDMA (3GPP FDD) band 11, UE test signaling software (R&S®CMU200-B68, R&S®CMU200-B21 model 14 or 54, R&S®CMU200-B56 necessary)

1200.9258.02

R&S®CMU200-K56

HSUPA 5.7 Mbit/s extension, 3GPP/FDD/UE, Rel.6 (R&S®CMU-B68, R&S®CMU-B21 model 14 or 54, R&S®CMU-B56 necessary)

1200.7803.02

R&S®CMU200-K57

WCDMA signaling 3GPP/FDD/UE, band 7 (R&S®CMU200-B68, R&S®CMU200-B21 model 14 or 54, R&S®CMU200-B56 necessary)

1200.7903.02

R&S®CMU200-K58


1200.8000.02

R&S®CMU200-K59


1200.8100.02

R&S®CMU200-K60 HSDPA 14 Mbit/s extension 3GPP/FDD/UE, Rel. 5 (¸CMU-K64 necessary) 1200.8200.02

R&S®CMU200-K61 WCDMA (3GPP FDD) band 4, UE test signaling software 1157.3670.02



R&S®CMU200-K64 3.6 Mbit/s HSDPA 1157.3970.02

R&S®CMU200-K65

WCDMA (3GPP FDD) UL user equipment TX test, non-signaling test software

1115.4891.02

R&S®CMU200-K66 WCDMA (3GPP FDD) DL generator, non-signaling test software 1115.5100.02




About Rohde & Schwarz Rohde & Schwarz is an independent group of companies specializing in electronics. It is a leading supplier of solutions in the fields of test and measurement, broadcasting, radiomonitoring and radiolocation, as well as secure communications. Established 75 years ago, Rohde & Schwarz has a global presence and a dedicated service network in over 70 countries. Company headquarters are in Munich, Germany.

Regional contact Europe, Africa, Middle East +49 1805 12 42 42* or +49 89 4129 137 74 [email protected]

North America 1-888-TEST-RSA (1-888-837-8772) [email protected]

Latin America +1-410-910-7988 [email protected]

Asia/Pacific +65 65 13 04 88 [email protected]

This application note and the supplied programs may only be used subject to the conditions of use set forth in the download area of the Rohde & Schwarz website.

Rohde & Schwarz GmbH & Co. KG Mühldorfstraße 15 | D - 81671 München Phone + 49 89 4129 - 0 | Fax + 49 89 4129 – 13777 www.rohde-schwarz.com

1CM73_1E(2)

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